Your search keyword '"D. W. Dugan"' showing total 5 results

1. Evaluation of Fluid Behavior in Spinning Toroidal Tanks

Author

D. A. Fester, J. E. Anderson, and D. W. Dugan

Subjects

Propellant, Engineering, Materials science, Toroid, Spacecraft, business.industry, Slosh dynamics, Aerospace Engineering, Mechanics, law.invention, Ullage, Orbiter, Settling, Space and Planetary Science, law, Astrophysics::Earth and Planetary Astrophysics, Aerospace engineering, business, Spinning

Abstract

An experimental study was conducted to evaluate propellant behavior in spinning toroidal tanks that could be used in a retro-propulsion system of an advanced outer-planet Pioneer orbiter. Information on propellant slosh and settling and on ullage orientation and stability was obtained. The effects of axial acceleration, spin rate, spin rate change, and spacecraft wobble, both singly and in combination, were evaluated using a 1/8-scale transparent tank in one-g and low-g environments. Liquid loadings ranged from 5% to 96% full. The impact of a surface tension acquisition device was assessed. Testing simulated the behavior of F2/N2H4 and N2O4/MMH propellants. Results are presented which indicate no major fluid behavior problems would be encountered with any of the four propellants in the toroidal tanks of a spin-stabilized orbiter spacecraft.

Published

1977

2. A feasibility study of developing toroidal tanks for a spinning spacecraft

Author

J. E. Anderson, D. A. Fester, and D. W. Dugan

Subjects

Propellant, Fabrication, Toroid, Materials science, Spacecraft, business.industry, law.invention, Physics::Fluid Dynamics, Surface tension, Orbiter, law, Systems design, Aerospace engineering, business, Spinning

Abstract

The use of toroidal tanks in an advanced Pioneer, spin-stabilized Jupiter orbiter was investigated. Fluid behavior in spinning toroids was evaluated and the need for a propellant acquisition system was established. A common surface tension acquisition system design was selected from four candidates for gas-free liquid feed to a single outlet in both MMH and N2O4 tanks. Fabrication of toroidal tanks using either titanium or aluminum alloys is feasible. Integration of two toroidal tanks with surface tension systems in place of four spherical tanks provides spacecraft weight, packaging, structural mounting, thermal control and stability advantages.

Published

1974

3. Description of a New 63-M M Diameter Gas Gun Facility

Author

D. W. Dugan and S. A. Sheffield

Subjects

Shock wave, Engineering, Explosive material, Projectile, business.industry, Nuclear engineering, Mechanical engineering, Impact test, Turnaround time, law.invention, Shock (mechanics), Shot (pellet), law, Light-gas gun, business

Abstract

This paper describes a new light gas gun that is just being completed at Sandia National Laboratories, primarily for use in the study of shock initiation and shock properties of explosive materials. This gun was patterned after the 100-mm diameter gas gun at Washington State University[1]. Several unique features have been designed into the facility to make it easier to control and use the gun and to improve shot turnaround time. These will be discussed in some detail in the sections that follow. Initial gun performance information will also be presented.

Published

1986

4. Advanced bipropellant systems for use on planetary orbiters

Author

H. F. Meissinger, W. L. Davenport, and D. W. Dugan

Subjects

Physics, Spacecraft, business.industry, Cost effectiveness, Payload, In-space propulsion technologies, Space Shuttle, Liquid rocket propellants, Spacecraft design, law.invention, Orbiter, law, Aerospace engineering, business

Abstract

Planetary orbit mission capabilities will be greatly improved by the advent of space-storable retro-propulsion systems with liquid fluorine/hydrazine as bipropellants, even when the Space Shuttle/Space Tug is used as launch vehicle. With a specific impulse as high as 375 sec, a multimission propulsion module designed for Pioneer or Mariner class spacecraft as payload and using space-storable propellants, can perform Mercury, Saturn and Uranus orbiter missions, and even some comet rendezvous missions. It also can reduce trip times to the outer planets significantly. The paper presents mission requirements, propulsion technology status, system design, performance, development schedules and cost data, based on results of a recent design and feasibility study.

Published

1975

5. Improved planetary orbit mission capabilities in the Shuttle era by use of space-storable propulsion systems

Author

H. F. Meissinger and D. W. Dugan

Subjects

Physics, Spacecraft propulsion, Spacecraft, Payload, business.industry, Cost effectiveness, In-space propulsion technologies, Space Shuttle, Propulsion, law.invention, Orbiter, law, Aerospace engineering, business

Abstract

Planetary-orbit mission capabilities will be greatly improved by the advent of space-storable retropropulsion systems with liquid fluorine and hydrazine as bipropellants even when the Shuttle/Tug is used as launch vehicle. Having a specific impulse as large as 375 sec, a multimission propulsion module using space-storable propellants with Pioneer or Mariner spacecraft as payload can perform Mercury, Saturn, and Uranus orbiter missions, and even some comet rendezvous missions, more cost effectively and flexibly than one using earth-storable propellants. It also can reduce trip time to the outer planets significantly. This paper presents mission requirements, technology status, system design and performance, development schedules, and costs based on data derived in a recent design and feasibility study.

Published

1975