Your search keyword '"Domínguez, R.M."' showing total 2 results

1. RF Helicon-based Inductive Plasma Thruster (IPT) Design for an Atmosphere-Breathing Electric Propulsion system (ABEP).

Author

Romano, F., Chan, Y.-A., Herdrich, G., Traub, C., Fasoulas, S., Roberts, P.C.E., Smith, K., Edmondson, S., Haigh, S., Crisp, N.H., Oiko, V.T.A., Worrall, S.D., Livadiotti, S., Huyton, C., Sinpetru, L.A., Straker, A., Becedas, J., Domínguez, R.M., González, D., and Cañas, V.

Subjects

*ELECTRIC propulsion, *PROPULSION systems, *DRAG (Aerodynamics), *PLASMA waves, *OXYGEN, *PLANETARY atmospheres, *RADIO frequency

Abstract

Challenging space missions include those at very low altitudes, where the atmosphere is source of aerodynamic drag on the spacecraft. To extend such missions lifetime, an efficient propulsion system is required. One solution is Atmosphere-Breathing Electric Propulsion (ABEP). It collects atmospheric particles to be used as propellant for an electric thruster. The system would minimize the requirement of limited propellant availability and can also be applied to any planet with atmosphere, enabling new mission at low altitude ranges for longer times. Challenging is also the presence of reactive chemical species, such as atomic oxygen in Earth orbit. Such species cause erosion of (not only) propulsion system components, i.e. acceleration grids, electrodes, and discharge channels of conventional EP systems. IRS is developing within the DISCOVERER project, an intake and a thruster for an ABEP system. The paper describes the design and implementation of the RF helicon-based inductive plasma thruster (IPT). This paper deals in particular with the design and implementation of a novel antenna called the birdcage antenna, a device well known in magnetic resonance imaging (MRI), and also lately employed for helicon-wave based plasma sources in fusion research. This is aided by the numerical tool XFdtd®. The IPT is based on RF electrodeless operation aided by an externally applied static magnetic field. The IPT is composed by an antenna, a discharge channel, a movable injector, and a solenoid. By changing the operational parameters along with the novel antenna design, the aim is to minimize losses in the RF circuit, and accelerate a quasi-neutral plasma plume. This is also to be aided by the formation of helicon waves within the plasma that are to improve the overall efficiency and achieve higher exhaust velocities. Finally, the designed IPT with a particular focus on the birdcage antenna design procedure is presented. • Inductive plasma thruster: contactless device, avoids electrode erosion, adapts to any propellant. • Birdcage antenna design at resonance for an RF-fed thruster. • Partial acceleration of quasi-neutral plasma plume, does not need a neutralizer. • Collects and uses planet's atmosphere as propellant. • Compensates drag of satellites at very low altitudes (e.g. VLEO) to extend mission's life time and enable new mission scenarios. [ABSTRACT FROM AUTHOR]

Published

2020

2. The benefits of very low earth orbit for earth observation missions.

Author

Crisp, N.H., Roberts, P.C.E., Livadiotti, S., Oiko, V.T.A., Edmondson, S., Haigh, S.J., Huyton, C., Sinpetru, L.A., Smith, K.L., Worrall, S.D., Becedas, J., Domínguez, R.M., González, D., Hanessian, V., Mølgaard, A., Nielsen, J., Bisgaard, M., Chan, Y.-A., Fasoulas, S., and Herdrich, G.H.

Subjects

*SPACE vehicles, *DRAG (Aerodynamics), *SPACE debris, *ORBIT method, *LAUNCH vehicles (Astronautics), *ELECTRIC propulsion, *OXYGEN

Abstract

Very low Earth orbits (VLEO), typically classified as orbits below approximately 450 km in altitude, have the potential to provide significant benefits to spacecraft over those that operate in higher altitude orbits. This paper provides a comprehensive review and analysis of these benefits to spacecraft operations in VLEO, with parametric investigation of those which apply specifically to Earth observation missions. The most significant benefit for optical imaging systems is that a reduction in orbital altitude improves spatial resolution for a similar payload specification. Alternatively mass and volume savings can be made whilst maintaining a given performance. Similarly, for radar and lidar systems, the signal-to-noise ratio can be improved. Additional benefits include improved geospatial position accuracy, improvements in communications link-budgets, and greater launch vehicle insertion capability. The collision risk with orbital debris and radiation environment can be shown to be improved in lower altitude orbits, whilst compliance with IADC guidelines for spacecraft post-mission lifetime and deorbit is also assisted. Finally, VLEO offers opportunities to exploit novel atmosphere-breathing electric propulsion systems and aerodynamic attitude and orbit control methods. However, key challenges associated with our understanding of the lower thermosphere, aerodynamic drag, the requirement to provide a meaningful orbital lifetime whilst minimising spacecraft mass and complexity, and atomic oxygen erosion still require further research. Given the scope for significant commercial, societal, and environmental impact which can be realised with higher performing Earth observation platforms, renewed research efforts to address the challenges associated with VLEO operations are required. • Very low Earth orbit (VLEO) can provide significant benefits over higher altitudes. • Higher resolution or lower cost missions can enabled by operating in VLEO. • Orbital debris collision risk and radiation damage are also shown to be reduced. • Launch vehicle capability is increased and end-of-life deorbit is facilitated. [ABSTRACT FROM AUTHOR]

Published

2020