Your search keyword '"Field-emission electric propulsion"' showing total 189 results

1. Emission Performance of Ionic Liquid Electrospray Thruster for Micropropulsion

Author

Xiong Cha, Huang Chengjin, Ting Si, Wei Fan, Mu Li, and Jianling Li

Subjects

Propellant, Electrospray, Materials science, business.industry, Mechanical Engineering, Aerospace Engineering, Ohnesorge number, Surface tension, chemistry.chemical_compound, Fuel Technology, chemistry, Space and Planetary Science, Ionic liquid, Field-emission electric propulsion, Weber number, CubeSat, Aerospace engineering, business

Abstract

It has been urgently required to develop ionic liquid electrospray thruster (ILET) for rapidly expanding micro-/nanosatellites. In this work, ILETs with high-density array emitters are fabricated t...

Published

2022

2. Plume Composition Measurements of a High-Emission-Density Electrospray Thruster

Author

Chengyu Ma, Thomas G. Bull, and Charles Ryan

Subjects

Propellant, 020301 aerospace & aeronautics, Electrospray, Materials science, business.industry, Mechanical Engineering, Aerospace Engineering, 02 engineering and technology, 01 natural sciences, 010305 fluids & plasmas, Plume, Fuel Technology, 0203 mechanical engineering, Space and Planetary Science, 0103 physical sciences, Field-emission electric propulsion, Optoelectronics, business, Porous medium, Electrical impedance

Abstract

An electrospray thruster designed for nanosatellites is introduced in this paper. The thruster has a compact size featuring a passive propellant transport method through the use of porous materials...

Published

2021

3. Survey on Research and Development of Field Emission Electric Propulsion Thrusters

Author

In-Seuck Jeung, Bok Jik Lee, and Jeongjae Park

Subjects

Materials science, business.industry, Field-emission electric propulsion, Aerospace engineering, business

Published

2021

4. The Next Generation Gravity Mission and the qualification of the indium-fed mN-FEEP thruster

Author

Alexander Reissner, David Krejci, P. Silvestrin, J. Gonzalez del Amo, Bernhard Seifert, and Luca Massotti

Subjects

Propellant, Earth observation, business.industry, Aerospace Engineering, Propulsion, Electrically powered spacecraft propulsion, Gravitational field, Space and Planetary Science, Field-emission electric propulsion, Environmental science, Specific impulse, Aerospace engineering, business, Constellation

Abstract

ESA’s Next Generation Gravity Mission (NGGM) is a candidate Mission of Opportunity for ESA-NASA cooperation in the frame of the MAss change and Geosciences International Constellation (MAGIC) . The mission aims at enabling long-term monitoring of the temporal variations of Earth’s gravity field at relatively high temporal (down to 3 days) and increased spatial resolutions (up to 100 km) at longer time. Such variations carry information about mass change induced by the water cycle and the related mass exchange among atmosphere, oceans, cryosphere, and land, and will complete our picture of global and climate change with otherwise partial or unavailable data. Over the last 15 years, numerous system and technology activities have been initiated by the Earth Observation Programmes (EOP) Directorate of the European Space Agency with the aim of advancing the maturity of the NGGM system and the key subsystems: particular attention was devoted to the design of the fine attitude control system, enabled by proportional thruster like variable specific impulse electrostatic thrusters based on Field Emission Electric Propulsion (FEEP), in which a liquid propellant is electrostatically extracted and accelerated to high exhaust velocity. The core element of this propulsion technology is a passively-fed, porous tungsten crown emitter, consisting of 28 sharp needles. This emitter technology has been developed and qualified over more than a decade at FOTEC and the Austrian Institute of Technology under ten ESA/EOP contracts since 2005 targeting the NGGM needs and it has recently been adapted for use as the main propulsion system in commercial nano- and small-satellites. This paper summarizes the development efforts of the last decade and provides an assessment of the performance of this thruster technology, after extensive simulation and testing campaigns.

Published

2021

5. Metal Plasma Thruster for Small Satellites

Author

Simon Leemans, Katherine Velas, and Mahadevan Krishnan

Subjects

Materials science, Aerospace Engineering, 02 engineering and technology, 01 natural sciences, 010305 fluids & plasmas, law.invention, Metal, 0203 mechanical engineering, law, 0103 physical sciences, Nano, Pulsed plasma thruster, Aerospace engineering, Thrust vectoring, Propellant, 020301 aerospace & aeronautics, Power processing unit, business.industry, Mechanical Engineering, technology, industry, and agriculture, Plasma, Fuel Technology, Space and Planetary Science, visual_art, Field-emission electric propulsion, visual_art.visual_art_medium, business

Abstract

This paper describes a metal plasma thruster (MPT) that is suited to nano- and microsatellites. The MPT uses solid metal propellant (hence requires no liquids, gases, flow valves, or flow controls)...

Published

2020

6. Recommended Practice for Thrust Measurement in Electric Propulsion Testing

Author

Scott King, Anthony Pancotti, James E. Polk, Joseph Blakely, John Ziemer, Mitchell L. R. Walker, and Thomas W. Haag

Subjects

010302 applied physics, Propellant, Engineering, business.industry, Mechanical Engineering, Aerospace Engineering, Mechanical engineering, Thrust, Thrust-to-weight ratio, Impulse (physics), 01 natural sciences, Article, 010305 fluids & plasmas, Fuel Technology, Electrically powered spacecraft propulsion, Space and Planetary Science, 0103 physical sciences, Field-emission electric propulsion, business

Abstract

Accurate, direct measurement of thrust or impulse is one of the most critical elements of electric thruster characterization, and one of the most difficult measurements to make. This paper summarizes recommended practices for the design, calibration, and operation of pendulum thrust stands, which are widely recognized as the best approach for measuring μN- to mN-level thrust and μNs-level impulse bits. The fundamentals of pendulum thrust stand operation are reviewed, along with the implementation of hanging pendulum, inverted pendulum, and torsional balance configurations. Methods of calibration and recommendations for calibration processes are presented. Sources of error are identified and methods for data processing and uncertainty analysis are discussed. This review is intended to be the first step toward a recommended practices document to help the community produce high quality thrust measurements.

Published

2021

7. Highly miniaturized FEEP propulsion system (NanoFEEP) for attitude and orbit control of CubeSats

Author

Martin Tajmar and Daniel Bock

Subjects

Physics, Propellant, business.industry, Aerospace Engineering, Thrust, Propulsion, 01 natural sciences, 010305 fluids & plasmas, Attitude control, Electrically powered spacecraft propulsion, 0103 physical sciences, Field-emission electric propulsion, CubeSat, Electronics, Aerospace engineering, business, 010303 astronomy & astrophysics

Abstract

A highly miniaturized Field Emission Electric Propulsion (FEEP) system is currently under development at TU Dresden, called NanoFEEP [ 1 ]. The highly miniaturized thruster heads are very compact and have a volume of less than 3 cm3 and a weight of less than 6 g each. One thruster is able to generate continuous thrust of up to 8 μN with short term peaks of up to 22 μN. The very compact design and low power consumption (heating power demand between 50 and 150 mW) are achieved by using Gallium as metal propellant with its low melting point of approximately 30 °C. This makes it possible to implement an electric propulsion system consisting of four thruster heads, two neutralizers and the necessary electronics on a 1U CubeSat with its strong limitation in space, weight and available power. Even formation flying of 1U CubeSats using an electric propulsion system is possible with this system, which is shown by the example of a currently planned cooperation project between Wuerzburg University, Zentrum fuer Telematik and TU Dresden. It is planned to use the NanoFEEP electric propulsion system on the UWE (University Wuerzburg Experimental) 1U CubeSat platform [ 2 ] to demonstrate orbit and two axis attitude control with our electric propulsion system NanoFEEP. We present the latest performance characteristics of the NanoFEEP thrusters and the highly miniaturized electronics. Additionally, the concept and the current status of a novel cold neutralizer chip using Carbon Nano Tubes (CNTs) is presented.

Published

2018

8. Characteristics of liquid film on the tip surface of indium field-emission electric propulsion thrusters

Author

Xinyu Liu, Dengshuai Guo, Xiaoming Kang, and Weiguo He

Subjects

Propellant, Surface (mathematics), Work (thermodynamics), Materials science, business.industry, Mechanical Engineering, Aerospace Engineering, chemistry.chemical_element, Taylor cone, Physics::Fluid Dynamics, Liquid film, Electrically powered spacecraft propulsion, chemistry, Field-emission electric propulsion, Optoelectronics, business, Indium

Abstract

The characteristics of the propellant film on the tip surface of the field-emission electric propulsion thruster have a close relationship with the work state of the thruster. In this paper, the distributions of both the liquid film thickness and the fluid velocity along the needle tip have been calculated by building the liquid mechanics equations and a cone coordinate system suitable for the tip. The results show that the film thickness is tens to hundreds of nanometers and the fluid velocity along the needle tip is from tens of µm/s to a few mm/s.

Published

2017

9. Near Time-Minimal Earth to L1 Transfers for Low-Thrust Spacecraft

Author

Helen C. Henninger and James D. Biggs

Subjects

Physics, Propellant, Orbital elements, 0209 industrial biotechnology, Spacecraft, business.industry, Applied Mathematics, Aerospace Engineering, Thrust, 02 engineering and technology, 01 natural sciences, Astrobiology, 020901 industrial engineering & automation, Standard gravitational parameter, Space and Planetary Science, Control and Systems Engineering, 0103 physical sciences, Field-emission electric propulsion, Earth (chemistry), Electrical and Electronic Engineering, Aerospace engineering, business, 010303 astronomy & astrophysics

Published

2017

10. Investigating a two-stage electric space propulsion system: Simulation of plasma dynamics

Author

Manish Jugroot and Alex Christou

Subjects

010302 applied physics, Physics, Ion thruster, business.industry, Variable Specific Impulse Magnetoplasma Rocket, Condensed Matter Physics, 01 natural sciences, Electrostatic ion thruster, Cold gas thruster, 010305 fluids & plasmas, Surfaces, Coatings and Films, Electrically powered spacecraft propulsion, 0103 physical sciences, Field-emission electric propulsion, Colloid thruster, Pulsed inductive thruster, Aerospace engineering, business, Instrumentation

Abstract

Electric propulsion presents an excellent alternative to conventional chemical counterparts as higher exhaust velocities from a plasma-based thruster allow for more efficient mass utilization and expanded space mission capabilities. Understanding the detailed time and space dependant physical phenomena within the main thruster could potentially enhance the capabilities of the electric thruster. Hence, in the present work a two-stage Hall thruster is investigated and the potential feasibility of coupling the two stages to produce the ion-beam is evaluated. The ionization and acceleration events are investigated via multiphysics simulations. The key trends ranging from the discharge inception, amplification and drift to formation of the ion beam are discussed and characterized.

Published

2017

11. Numerical Analysis of Ion Behavior Considering Charging Effect of a Dielectric Body

Author

Katsuhiro Hirata, Shuhei Matsuzawa, Yamamoto Takeshi, and Tomohiro Ota

Subjects

Materials science, Dielectric, 01 natural sciences, Electric charge, Ion, Ion wind, Ionic potential, Physics::Plasma Physics, Electric field, 0103 physical sciences, Electrical and Electronic Engineering, Physics, 010302 applied physics, business.industry, Electrical engineering, Finite element method, Electronic, Optical and Magnetic Materials, Polarization density, Electrode, Field-emission electric propulsion, Particle, Electric discharge, Electric potential, Atomic physics, business, Intensity (heat transfer)

Abstract

This paper proposes a coupled analysis method to deal with ion generation and ion drift in the air. Electric discharge is utilized in various products, and it is very important to clarify not only how much ion is generated but also where ion drifts in the air. The proposed method, which modeled interactions between electric field and ion behavior, including ion generation, ion drift, and charging of a dielectric body, has succeeded in calculating charge removal of a metallic target, which was tens of millimeters away from a pin electrode as a source of generated ion. The calculated results show that the amount of generated ion is drastically changed because electric field is affected by electric charge of ion in the air and charging of a dielectric body. This paper also reports a comparison of measured and calculated results of charge removal time of a metallic target, which were found to be in good agreement.

Published

2017

12. Recommended Practice for Use of Faraday Probes in Electric Propulsion Testing

Author

Daniel L. Brown, Mitchell L. R. Walker, John E. Foster, James Szabo, and Wensheng Huang

Subjects

010302 applied physics, Propellant, Engineering, Ion thruster, business.industry, Mechanical Engineering, Aerospace Engineering, 01 natural sciences, 010305 fluids & plasmas, law.invention, Fuel Technology, Electrically powered spacecraft propulsion, Space and Planetary Science, law, Hall effect, 0103 physical sciences, Field-emission electric propulsion, Electronic engineering, Aerospace engineering, business, Faraday cage, Magnetoplasmadynamic thruster, Space environment

Abstract

Faraday probes are a common plasma diagnostic used to determine the local ion charge flux of electric propulsion plumes. Standard practices, guidelines, and recommendations are provided for experimental methods and analysis techniques that aim to standardize community practices, to mitigate test environment effects, and to reduce systematic measurement error in order to improve plume predictions in the space environment. The approaches are applicable to time-averaged plasma properties in the near-field and far-field of electric propulsion plumes, with emphasis on Hall effect thrusters and gridded ion thrusters. Considerations for other electric propulsion technologies are provided, including electrosprays, arcjets, and electromagnetic thruster concepts. These test strategies are expected to increase the quality of comparisons between different thrusters and vacuum environments, thereby broadening the applicability of ground-based measurements and enhancing the fidelity for on-orbit predictions and modelin...

Published

2017

13. Three-dimensional particle simulation of back-sputtered carbon in electric propulsion test facility

Author

Hongru Zheng, Liu Lihui, Guobiao Cai, Shang Shengfei, and Bijiao He

Subjects

Materials science, Ion beam, Ion thruster, Aerospace Engineering, 02 engineering and technology, Mechanics, Sputter deposition, 021001 nanoscience & nanotechnology, 01 natural sciences, Electrically powered spacecraft propulsion, Sputtering, 0103 physical sciences, Field-emission electric propulsion, Vacuum chamber, Pulsed inductive thruster, 0210 nano-technology, 010303 astronomy & astrophysics, Simulation

Abstract

The back-sputtering deposition on thruster surface caused by ion bombardment on chamber wall material affects the performance of thrusters during the ground based electric propulsion endurance tests. In order to decrease the back-sputtering deposition, most of vacuum chambers applied in electric propulsion experiments are equipped with anti-sputtering targets. In this paper, a three-dimensional model of plume experimental system (PES) including double layer anti-sputtering target is established. Simulation cases are made to simulate the plasma environment and sputtering effects when an ion thruster is working. The particle in cell (PIC) method and direct simulation Monte Carlo (DSMC) method is used to calculate the velocity and position of particles. Yamamura's model is used to simulate the sputtering process. The distribution of sputtered anti-sputtering target material is presented. The results show that the double layer anti-sputtering target can significantly reduce the deposition on thruster surface. The back-sputtering deposition rates on thruster exit surface for different cases are compared. The chevrons on the secondary target are rearranged to improve its performance. The position of secondary target has relation with the ion beam divergence angle, and the radius of the vacuum chamber. The back-sputtering deposition rate is lower when the secondary target covers the entire ion beam.

Published

2017

14. Three-Dimensional Simulations of Backflows from Ion Thruster Plumes Using Unstructured Grid Refinement

Author

Deborah A. Levin and Burak Korkut

Subjects

Physics, 020301 aerospace & aeronautics, Ion thruster, Adaptive mesh refinement, Mechanical Engineering, Aerospace Engineering, 02 engineering and technology, 01 natural sciences, 010305 fluids & plasmas, Ion, Unstructured grid, Computational physics, Momentum, Fuel Technology, 0203 mechanical engineering, Physics::Plasma Physics, Space and Planetary Science, Electric field, 0103 physical sciences, Field-emission electric propulsion, Atomic physics, Backflow

Abstract

Ion thruster plumes are simulated under a framework that was recently developed to take advantage of the large scalability of unstructured grids using adaptive mesh refinement. Momentum and charge-exchange collisions occurring between neutral and ion species, as well as the induced electric field due to ions, have been performed using multiple adaptive mesh refinement meshes to study the backflow of an ion thruster to a spacecraft surface. Furthermore, the ions and neutral species are directly coupled, which is found to have a 15% effect on the neutral species velocity profiles. The backflow for ions is found to occur when charge-exchange and momentum-exchange collisions are present, and then it is strongly enhanced when the induced electric field is considered. The ion energy distributions in the backflow region are obtained, and it is found that the inclusion of the electric field modeling is the most important factor in determining its shape. The plume backflow structure is also examined for a triple-t...

Published

2017

15. Experimental research of radio-frequency ion thruster

Author

R. V. Akhmetzhanov, N. N. Antropov, S. A. Khartov, R. A. Grishin, V. V. Kozhevnikov, A. V. Bogatyy, G. A. Popov, and A. P. Plokhikh

Subjects

Ion thruster, 010308 nuclear & particles physics, Chemistry, business.industry, Energy Engineering and Power Technology, Mechanical engineering, 01 natural sciences, Electrostatic ion thruster, Cold gas thruster, Nuclear Energy and Engineering, Electrically powered spacecraft propulsion, 0103 physical sciences, Field-emission electric propulsion, Electrodeless plasma thruster, Colloid thruster, Pulsed inductive thruster, Aerospace engineering, 010306 general physics, business

Abstract

The article is devoted to the research of low-power (300 W) radio-frequency ion thruster designed at the Moscow Aviation Institute. The main results of experimental research of the thruster using the testfacility power supplies and the power processing unit of their own design are presented. The dependence of the working fluid ionization cost on its mass flow rate at the constant ion beam current was investigated experimentally. The influence of the shape and material of the discharge chamber on the integral characteristics of the thruster was studied. The recommendations on the optimization of the thruster primary performance were developed based on the results of experimental studies.

Published

2016

16. Design and fabrication of field‐emission tips with self‐aligned gates

Author

Ryan E. Hainley, Bobby Reddy, William C. Tang, and Eric Codner

Subjects

Technology, masks, Materials science, Fabrication, hydrofluoric-nitric-acetic acids, Biomedical Engineering, Bioengineering, Nanotechnology, 02 engineering and technology, SiN, Photoresist, 010402 general chemistry, field-emission tip design, electrostatic simulations, 01 natural sciences, metal layer, Engineering, field-emission tip fabrication, spin coating, Etching (microfabrication), etching, self-aligned gates, General Materials Science, Nanoscience & Nanotechnology, SU-8 photoresist, microelectromechanical system fabrication process, microfabrication, electric field enhancement, wetting, Spin coating, field-emission flat-panel display applications, electric propulsion, hard mask, field emitter arrays, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Isotropic etching, 0104 chemical sciences, micron-sized tip array, silicon wet isotropic etching, photoresists, gate electrode, Field-emission electric propulsion, silicon compounds, electric propulsion microthruster applications, 0210 nano-technology, dielectric spacer, Microfabrication

Abstract

A novel approach to the design and fabrication of field-emission tips with self-aligned gates intended for electric propulsion micro-thruster applications is presented. Their micro-electromechanical systems fabrication process is derived from the recent proliferation of research toward developing field emitter arrays, which are used primarily for field-emission flat-panel display applications. An array of micron-sized tips for electric field enhancement via wet isotropic etching of silicon, using silicon nitride as a hard mask is fabricated. The wet etching is accomplished using a combination of hydrofluoric, nitric, and acetic acids. The tips were then coated with a metal layer to enhance wetting by indium, the proposed propellant. Next, a layer of SU-8 photoresist was applied by spin coating and patterned to serve as a dielectric spacer. A second layer of metal was then applied to serve as a gate electrode. In addition, the results of electrostatic simulations of the prototype is described.

Published

2016

17. Vacuum solid-state ion-conducting silver source for application in field emission electric propulsion systems

Author

S. F. Belykh, Alexander Tolstogouzov, D. V. Suvorov, R. Schwarz, R. Ayouchi, Fábio Fernandes, Hugo Águas, Gennady P. Gololobov, Augusto M.C. Moutinho, and Orlando M. N. D. Teodoro

Subjects

010302 applied physics, Chemistry, Analytical chemistry, Ion current, 02 engineering and technology, Electrolyte, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Evaporation (deposition), Surfaces, Coatings and Films, Ion, Pulsed laser deposition, Electric field, 0103 physical sciences, Field-emission electric propulsion, Thin film, 0210 nano-technology, Instrumentation

Abstract

A point-like silver ion source with thin film of RbAg 4 I 5 solid electrolyte was developed for application in field emission electric propulsion systems. The solid electrolyte produced by mechano-chemical synthesis was deposited on the apex of a silver tip using pulsed laser deposition. The running tests at 195 °C working temperature and 10 kV accelerating potential have demonstrated that the source can continuously produce positive ion current of several hundred pA during a few days with a peak value of 25–50 nA. Using TOF-SIMS analysis it has been shown that the ion current consists of Ag + with a small contribution of Rb + , lower than 0.5 at.%. We suggest that Ag + emission occurs mainly by means of field-assisted ion evaporation and/or ion desorption, and the solid electrolyte plays a role of the transport system, in which the emitted Ag + ions are continually replaced by mobile Ag + ions delivered from the silver reservoir by direct mass transfer under the influence of an external electric field.

Published

2016

18. Characterisation of anomalous forces on asymmetric high‐voltage capacitors

Author

Elio B. Porcelli and Victo S. Filho

Subjects

010302 applied physics, Materials science, business.industry, Electrical engineering, Mechanics, Dielectric, 01 natural sciences, Clausius–Mossotti relation, Atomic and Molecular Physics, and Optics, 010305 fluids & plasmas, law.invention, Capacitor, Dipole, Electric dipole moment, law, Electric field, 0103 physical sciences, Field-emission electric propulsion, Electric potential, Electrical and Electronic Engineering, business

Abstract

In this study, the authors analysed an anomalous force observed in asymmetric capacitors, working in high electric potentials. From a lot of experimental measurements performed in their asymmetric capacitor, they detected real variations of the device inertia. An empirical formula of the developed force according to Clausius–Mossotti relation explained the experimental results with good agreement, suggesting that the anomalous force can be related directly to the electric dipoles inside the capacitor dielectric. They could also explain why that force always points toward the small electrode when it is subjected to a convergent electric field. Such simple electrical propulsion systems could allow in the future the substitution of the fuel propulsion technology.

Published

2016

19. Investigation of Variation in the Performance of an Electro Thermal Thruster with Aerospike Nozzle

Author

Pranav Menon

Subjects

Engineering, Ion thruster, Spacecraft propulsion, business.industry, Mechanical engineering, General Medicine, Characteristic velocity, Propulsion, Electrically powered spacecraft propulsion, Field-emission electric propulsion, Pulsed inductive thruster, Colloid thruster, Aerospace engineering, business

Abstract

One of the most recently developed modes of propulsion is electric propulsion. The commonly used chemical propulsion systems have the advantage of a high Specific Impulse as compared to that of ion propulsion systems. However, owing to the efficacy of ion propulsion systems, it is considered the future of space exploration.Electro thermal thrusters produce thrust by using electrical fields to force hot plasma out of the nozzle with certain exit velocity. The plasma’s exit velocity and the system’s thrust capacity, as of now, are insufficient for space travel to be conducted within a reasonable time. I intend to study the possibility of improving the thruster’s performance by using an aerospike nozzle as an exit nozzle which meets the conditions required for the thruster to function appropriately. I shall be studying the plasma plume exit velocity variation with respect to the nozzles used. Also, a thermal analysis will be conducted in order to find the correct material for the nozzle.

Published

2016

20. Investigation of the accelerating electric fields in laser-induced ion beams

Author

V. Nassisi, D. Delle Side, and E. Giuffreda

Subjects

Nuclear and High Energy Physics, Field (physics), Chemistry, Laser, 01 natural sciences, Ion source, 010305 fluids & plasmas, law.invention, Ion, Acceleration, law, Electric field, 0103 physical sciences, Field-emission electric propulsion, Electric potential, Atomic physics, 010306 general physics, Instrumentation

Abstract

The Front Surface Acceleration (FSA) obtained in Laser Ion Source (LIS) systems is one of the most interesting methods to produce accelerated protons and ions. We implemented a LIS to study the electric field responsible for the ion acceleration mechanisms. A high impedance resistive probe was used to map the electric potential inside the chamber, near the target. We detected the time resolved profiles of the electric potential moving the probe from 4.7 cm to 6.2 cm with respect to the main target axis. The corresponding electric field depends on the distance x as 1 / x α with α ∼ 1.8 . We suggest that the electric field strength stems from the contribution of an electrostatic and an induced field.

Published

2017

21. Direct Thrust and Plume Divergence Measurements of the IFM Nano Thruster

Author

Alexander Reissner, David Jelem, N. Buldrini, Lissa Wilding, David Krejci, and Bernhard Seifert

Subjects

020301 aerospace & aeronautics, Atmospheric Science, business.industry, Aerospace Engineering, Astronomy and Astrophysics, Thrust, Ion current, 02 engineering and technology, Propulsion, 021001 nanoscience & nanotechnology, 7. Clean energy, Plume, Geophysics, 0203 mechanical engineering, Space and Planetary Science, Range (aeronautics), Field-emission electric propulsion, General Earth and Planetary Sciences, Aerospace engineering, 0210 nano-technology, business, Geology, Common emitter, Voltage

Abstract

The IFM Nano Thruster, which consists of a porous tungsten crown ion-emitter to provide thrust in the range of 10 µN to 1 mN at 2000–5000 s ISP, has been tested on a µN thrust balance that has previously been verified at the ESA Propulsion Laboratories. A comprehensive assessment of the thrust performance has been complemented by measurements of the plume divergence using a novel segmented collector setup that allows to assess the ion current distribution within a 2D-section of the plume in a high time resolution. From the plasma probe measurements, an upper bound of 0.93 for the thrust coefficient has been derived, while direct thrust measurements have shown a thrust coefficient between 0.8 and 0.9 over the entire thrust range. From the test results, a complete thruster performance map could be established linking emitter current and voltage with thrust and Isp.

Published

2018

22. Permanent magnet Hall thruster development for future Brazilian space missions

Author

Artur C. B. Serra, Jose Leonardo Ferreira, Felipe Nathan, Ernesto Gonçalves Costa, Laís de Souza Alves, A. B. Schelin, Rodrigo A. Miranda, Alexandre A. Martins, and Herbert O. Coelho

Subjects

Physics, Ion thruster, business.industry, Applied Mathematics, Plasma propulsion engine, 02 engineering and technology, Variable Specific Impulse Magnetoplasma Rocket, 01 natural sciences, 010305 fluids & plasmas, law.invention, Computational Mathematics, Nuclear magnetic resonance, Electrically powered spacecraft propulsion, Physics::Plasma Physics, law, Physics::Space Physics, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Electrodeless plasma thruster, Field-emission electric propulsion, 020201 artificial intelligence & image processing, Specific impulse, Pulsed inductive thruster, Aerospace engineering, business

Abstract

Electric propulsion is now a successful method for primary and secondary propulsion of deep space long-duration missions and for geosynchronous satellite attitude control. The Plasma Physics Laboratory of UnB has been developing a permanent magnet Hall thruster (PHALL) for the UNIESPACO program, part of the Brazilian space activities program (PNAE) since 2004. The idea of using an array of permanent magnets, instead of an electromagnet, to produce a radial magnetic field inside the plasma channel of the thruster is very significant. It allows the development of a Hall thruster with power consumption low enough to be used in small- and medium-size satellites. The PHALL project consists on plasma source design, construction and characterization of the Hall-type propulsion engine using several plasma diagnostics sensors. PHALL is based on a plasma source in which a Hall current is generated inside a cylindrical channel with an axial electric field produced by a ring anode and a radial magnetic field produced by permanent magnets. In this work, a brief description of the plasma propulsion engine, its diagnostics instrumentation and measured plasma parameters with a focus for possible applications of PHALL on orbit transfer maneuvering for future Brazilian geostationary satellite space missions is shown. More specifically, we will show plasma density and temperature space profiles inside and outside the thruster channel, ion temperature measurements based on Doppler broadening of spectral lines and ion energy measurements. Based on the measured plasma parameters we construct an aptitude figure of the PHALL. It contains the specific impulse, total thrust, propellant flow rate and power consumption necessary for orbit raising of satellites. Based on previous studies of geosynchronous satellite orbit positioning we perform numerical simulations of satellite orbit raising from an altitude of 700–36,000 km using a PHALL operating in the 100–500 mN thrust range. To perform these calculations integration techniques were used. The main simulation parameters were orbit raising time, fuel mass, total satellite mass, thrust and exhaust velocity. We conclude by comparing our results with results obtained with known space missions performed with Hall thrusters.

Published

2015

23. Analysis of Atmosphere-Breathing Electric Propulsion

Author

Georg Herdrich, Bartomeu Massuti-Ballester, Tony Schönherr, Kimiya Komurasaki, and Francesco Romano

Subjects

Nuclear and High Energy Physics, Ion thruster, business.industry, Electrical engineering, Variable Specific Impulse Magnetoplasma Rocket, Condensed Matter Physics, law.invention, Electrically powered spacecraft propulsion, law, Laser propulsion, Field-emission electric propulsion, Pulsed plasma thruster, Environmental science, Colloid thruster, Pulsed inductive thruster, Aerospace engineering, business

Abstract

To extend the lifetime of commercial and scientific satellites in low Earth orbit (LEO) and below (100–250 km of altitude) recent years showed an increased activity in the field of air-breathing electric propulsion as well as beamed-energy propulsion systems. However, preliminary studies showed that the propellant flow necessary for electrostatic propulsion at these altitudes exceeds the mass intake possible within reasonable limits, and that electrode erosion due to oxygen flow might limit the lifetime of eventual thruster systems. The pulsed plasma thruster (PPT), however, can be successfully operated with smaller mass intake and at relatively low power. This makes it an interesting candidate for air-breathing application in LEO and its feasibility is investigated within this paper. An analysis of such an air-breathing PPT system shows that for altitudes between 150 and 250 km, drag compensation is at least partially feasible assuming a thrust-to-power ratio of 30 mN/kW and a specific impulse of 5000 s. Further, to avoid electrode erosion, inductively heated electrothermal plasma generator technology is discussed to derive a possible propulsion system that can handle gaseous propellant without unfavorable side effects. Current technology can be used to create an estimated 4.4 mN of thrust per 1 mg/s of mass flow rate, which is sufficient to compensate the drag for small satellites in altitudes between 150 and 250 km.

Published

2015

24. Electrohydrodynamics of cones on the surface of a liquid

Author

A. V. Subbotin

Subjects

Surface (mathematics), Materials science, Physics and Astronomy (miscellaneous), business.industry, Mechanics, Conductivity, Optics, Electric field, Field-emission electric propulsion, Vector field, Electrohydrodynamics, Current (fluid), business, Tangential and normal components

Abstract

Stationary structures formed on the surface of a liquid under the action of an electric field have been studied. With the use of the equations of electrohydrodynamics, it has been shown that cones are formed in a dynamic regime when the current of surface ions, which is induced by the tangential component of the electric field, dominates over the conductivity current in the bulk of a cone and the surface current induced by the flow of the liquid. The electric field strength both inside and outside the cone, as well as the velocity field inside the cone, has been determined. It has been shown that the angle of the cone depends on the current flowing on its surface. The characteristic size of the cone has been determined.

Published

2015

25. Operation of a Carbon Nanotube Field Emitter Array in a Hall Effect Thruster Plume Environment

Author

William Jud Ready, Mitchell L. R. Walker, Lake A. Singh, Graham P. Sanborn, and Stephan Turano

Subjects

Propellant, Nuclear and High Energy Physics, Materials science, Ion thruster, business.industry, Field emitter array, Electrical engineering, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, Condensed Matter Physics, Electrically powered spacecraft propulsion, Physics::Plasma Physics, Hall effect, Physics::Space Physics, Field-emission electric propulsion, Physics::Accelerator Physics, Optoelectronics, Pulsed inductive thruster, business, Common emitter

Abstract

The Hall effect thruster is an electric propulsion device for space applications that efficiently reduces the propellant mass requirements on a spacecraft in comparison with chemical rockets. To date, the Hall effect thruster technology relies on the thermionic cathodes that consume up to 10% of the total propellant used in the system to neutralize the ion beam of the thruster; however, such propellant usage does not contribute to thrust generation. An array of thin-film, carbon nanotube field emitters that emit electrons through field emission can potentially neutralize the ion beam without consuming any propellant. This paper examines the effects of 40 min exposure of carbon nanotube field emitter arrays to the plasma environment in the exit plane of a Hall effect thruster. The physical structures that enable field emission appear largely unaffected by placement in the plasma as well as operation in the plasma. This indicates that a refined design of this carbon nanotube field emitter array may potentially provide an alternative to the thermionic cathode used on contemporary Hall effect thrusters and verifies that no fundamental incompatibilities exist between these two technologies.

Published

2015

26. Revolutionary propulsion for future spacecraft: Field emission thruster developments at TU Dresden towards their first flight application

Author

Philipp Laufer, Martin Tajmar, and Daniel Bock

Subjects

Materials science, Spacecraft propulsion, Ion thruster, Electrically powered spacecraft propulsion, Spacecraft, business.industry, Field-emission electric propulsion, In-space propulsion technologies, CubeSat, Propulsion, Aerospace engineering, business

Abstract

The institute of aerospace engineering at TU Dresden is developing a highly miniaturized field emission electric propulsion (FEEP) system for Nano-satellites, called CubeSats. The presented propulsion system NanoFEEP is composed of the actual field emission thrusters and a carbon nanotubes silicon chip used as a cold electron source for neutralizing the electric charging behavior of the spacecraft. The NanoFEEP thrusters use Gallium as metal propellant and provide a continuous controllable thrust of up to 20 micro-newton. This thrust level is sufficient to control the attitude of the miniature CubeSat satellites and even perform orbit maneuvers. Two satellites missions will demonstrate these capabilities in the near future. One mission will show the feasibility of formation flying of CubeSats. The other mission will demonstrate the possibility of space debris avoidance with our propulsion system by deorbiting the satellite after mission completed.

Published

2017

27. Thrust Measurements of the Gaia Mission Flight-Model Cold Gas Thrusters

Author

C. Blanchard, P. Thobois, Denis Packan, L. Fallerini, G. Noci, Paul-Quentin Elias, and J. Jarrige

Subjects

Physics, business.industry, Mechanical Engineering, Pendulum, Aerospace Engineering, Thrust, Space exploration, Cold gas thruster, Fuel Technology, Space and Planetary Science, Range (aeronautics), Field-emission electric propulsion, Specific impulse, Aerospace engineering, business, Noise (radio)

Abstract

Thrust measurements are essential to qualify thrusters for space missions, especially for new technologies. In the framework of the Gaia mission, the 13 newly developed cold gas micronewton thrusters from Thales Alenia Space Italia (TAS-I) were subjected to acceptance tests on the micronewton thrust balance of ONERA in order to measure their thrust noise and specific impulse curve. The balance, based on the principle of a pendulum, has a high-thrust resolution (less than 0.1 μN), with a thrust noise of 0.1 μN/Hz in the range of 0.02–1 Hz. The calibration of the balance is presented, and the postprocessing corrections leading to this performance are detailed. The specific impulse of the 13 cold gas micronewton thrusters flight models has been measured for thrust levels in the range of 0.1–1000 μN, showing a slight increase of Isp from around 50 to 63 s with thrust for all flight models.

Published

2014

28. Non-stationary corona around multi-point system in atmospheric electric field: II. Altitude and time variation of electric field

Author

Yu. P. Raizer, E.M. Bazelyan, and Nickolay Aleksandrov

Subjects

Physics, Atmospheric Science, Gaussian surface, Geophysics, Optical field, Electric flux, Computational physics, Electric discharge in gases, symbols.namesake, Space and Planetary Science, Electric field, Field-emission electric propulsion, symbols, Corona ring, Electric potential

Abstract

The vertical electric field profile during thunderstorms was studied numerically and analytically above the plane ground surface with irregularities that generated ions when the surface electric field was sufficient for ion emission. The computer model of a plane emitting ions into the atmosphere simulated a limiting case of a non-stationary glow corona occurring near the tips of a multi-point ground system in a time-varying thundercloud electric field. The evolution of electric field profiles for various rates of change of thundercloud electric field was analyzed and the peculiarities of electric field measurements during thunderstorms were considered. A computer model was developed to estimate the temporal evolution of electric field above a multi-point coronating system. Conditions under which the electric field evolution above a multi-electrode system is similar to that above a plane emitting surface were determined. The evolution of the surface electric field below coronating points in a multi-electrode system was calculated. Conditions when the surface electric field tends to the thundercloud electric field necessary for corona onset in a multi-point system were obtained.

Published

2014

29. Measurement of liquid flow rate by self-generated electrokinetic potential on the microchannel surface of a solid

Author

Sung-Hoon Choa and Heesung Park

Subjects

Microchannel, Chemistry, Shear force, Metals and Alloys, Analytical chemistry, Mechanics, Slip (materials science), Condensed Matter Physics, Electric charge, Streaming current, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Physics::Fluid Dynamics, Electrokinetic phenomena, Field-emission electric propulsion, Electric potential, Electrical and Electronic Engineering, Instrumentation

Abstract

A model to describe the interactions between the electrokinetic potential and the liquid ion slip is proposed. The model assumes that the electric charge at the liquid and solid interface causes an attraction force, whereas the fluid shear force at the wall induces a frictional force. Using the proposed model, the condition underlying liquid ion slip is described by analyzing the generation of the surface electric potential when the shear force of flow is above 0.1 mN. Once liquid ion slip occurs, the electric charges at the interface move in the direction of the flow but are retarded by electric resistance. Thus, there is a difference in the surface electric potential generated at the solid wall in the direction of the flow. In the water flowing through the microchannel, the velocity of the liquid ion slip was 5.09 × 10 −5 to 2.19 × 10 −3 m/s, whereas the generated surface electric potential varied from 0 to 64 μV. The proposed model and the experimental analyses provide the groundwork for precise flow sensors, which could easily be integrated into microfluidic systems.

Published

2014

30. Characterization of electrospray beams for micro-spacecraft electric propulsion applications

Author

Manish Jugroot, Trevor Morris, and Cecile Malardier-Jugroot

Subjects

Propellant, Spacecraft, Ion thruster, business.industry, Chemistry, Propulsion, Condensed Matter Physics, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Electrically powered spacecraft propulsion, Physics::Space Physics, Field-emission electric propulsion, Specific impulse, Colloid thruster, Electrical and Electronic Engineering, Aerospace engineering, business, Biotechnology

Abstract

Electric propulsion for spacecraft offers many advantages compared to other traditional counterparts such as chemical propulsion. An electrostatic colloid thruster, well suited for small spacecrafts due to its inherent small size, is investigated. The underlying phenomena governing the plume, namely collisions and focusing are parameterized. The determining properties of the electrospray-based thruster, such as specific impulse, are measured for several propellants and demonstrated to be higher than cold-gas thrusters even for singly charged droplet mode. Moreover, the interesting concept of a dual colloid system with positively and negatively charged cone-jet beams was shown to be feasible by simulations and experiments.

Published

2013

31. Molecular Dynamics Simulations of a Liquid Gallium Electrospray Thruster

Author

Michael M. Micci and Dae Yong Kim

Subjects

Electrospray, Materials science, Capillary action, Mechanical Engineering, Aerospace Engineering, Molecular physics, Volumetric flow rate, Condensed Matter::Soft Condensed Matter, Physics::Fluid Dynamics, Condensed Matter::Materials Science, Molecular dynamics, Grand canonical ensemble, Fuel Technology, Space and Planetary Science, Electric field, Field-emission electric propulsion, Electric potential

Abstract

Molecular dynamics was used to simulate the operation of a liquid gallium electrospray thruster. Molecular dynamics calculates the motions of the ions and ion clusters of liquid gallium in a high electric field (∼1 V/nm) after they are extracted from a platinum capillary. Liquid gallium at 320 K is simulated with a modified ion–ion potential model. The platinum capillary at 320 K is modeled using a three-zone wall model with a Langevin thermostat, and the flow rate at 30 mm/s is generated by the fluidized piston model. The insertion part of a grand canonical ensemble (μVT) is adopted to supply ions of liquid gallium constantly into the platinum capillary. The electric potential and field generated by the extraction ring are solved by a combination of a finite element method and a finite difference method. The results of the simulations under several different operating conditions are used to characterize the performance of an electrospray thruster.

Published

2013

32. New materials and processes for field emission ion and electron emitters

Author

Bosun Jang and Martin Tajmar

Subjects

Materials science, Spacecraft propulsion, Field (physics), Aerospace Engineering, chemistry.chemical_element, Nanotechnology, Tungsten, law.invention, Selective laser sintering, Field electron emission, chemistry, Space and Planetary Science, law, Field-emission electric propulsion, Indium, Common emitter

Abstract

Indium field emission electric propulsion (FEEP) thrusters have been developed in the past as an enabling technology for ultraprecise formation flying applications such as on LISA Pathfinder. New missions require a large thrust range from μN into the mN range. A novel emitter type using micro-powder injection molding has been developed to produce porous tungsten crown emitters that promise very reliable and stable performance from sub-μN up to several hundred μN, as well as rapid manufacturing which had been a major issue in the past. Porous emitters were also investigated as electron emitters, which could enable bi-polar operation and therefore replace a separate neutralizer that is otherwise required. Recently, new materials such as rhenium and other manufacturing techniques including laser sintering were investigated to further explore the promising field of field emission technologies for space applications. This paper gives an overview on our recent porous emitter technology efforts and summarizes potential applications as well as terrestrial spin-off possibilities.

Published

2013

33. Performance Characterization of the Low-Power Halo Electric Propulsion System

Author

Charles Ryan, Aaron Knoll, T Wantock, and T Harle

Subjects

010302 applied physics, Engineering, Ion thruster, business.industry, Mechanical Engineering, Aerospace Engineering, Mechanical engineering, Variable Specific Impulse Magnetoplasma Rocket, Propulsion, 01 natural sciences, Cold gas thruster, 0901 Aerospace Engineering, 010305 fluids & plasmas, Fuel Technology, Electrically powered spacecraft propulsion, Space and Planetary Science, 0103 physical sciences, Physics::Space Physics, Field-emission electric propulsion, Aerospace & Aeronautics, Specific impulse, Pulsed inductive thruster, Aerospace engineering, business, 0913 Mechanical Engineering

Abstract

Performance measurements have been obtained of a novel propulsion concept called the Halo thruster under development within the University of Surrey. The Halo thruster, a type of cusped-field thruster with close similarity to the cylindrical Hall thruster, is motivated by the need for low-power and low-cost electric propulsion for the small satellite sector. Two versions of the device are investigated in this study: a design using permanent magnets at high magnetic-field strength and a design using electromagnets with moderate field strength. While operating at 200 W discharge power, which is of particular interest to power-limited small satellite platforms, the permanent-magnet design achieved a maximum thrust efficiency of 8% at a specific impulse of approximately 900 s using a krypton propellant. By comparison, the electromagnet design achieved a maximum thrust efficiency of 28% at a specific impulse of approximately 1500 s at 200 W using a xenon propellant. For higher levels of power (tested up to 800 W), the performance of the electromagnetic design saturated at approximately 25% thrust efficiency using krypton and 30% using xenon. The thrust efficiency of the permanent-magnet design appeared to increase monotonically up to 600 W reaching a maximum value of 14%.Read More: https://arc.aiaa.org/doi/abs/10.2514/1.B36091

Published

2016

34. Electric field analysis of different compact electrodes for pulsed electric field applications in liquid food

Author

Ramya Ramaswamy and Raja Prabu Ramachandran

Subjects

0301 basic medicine, 030109 nutrition & dietetics, Materials science, business.industry, Electrical engineering, Torus, High voltage, 02 engineering and technology, 021001 nanoscience & nanotechnology, 03 medical and health sciences, Electric field, Electrode, Electrode array, Field-emission electric propulsion, Optoelectronics, Electric potential, 0210 nano-technology, business, Voltage

Abstract

Electromagnetic simulation is performed on two compact electrode designs to obtain higher electric field distribution between high voltage and ground electrode, which ensures high bacterial inactivation in liquid food. Electric field simulations are performed initially for test voltages of 1kV to 5kV to understand the nature of electric field distribution in the inactivation area. Then the applied voltage is gradually increased to induce transmembrane potential on the cell membrane. The microorganism modeled for field analysis is Staphylococcus aureus. For both the round edged and torus tube designs, the transmembrane potential of 0.5V to 1V is achieved with the spherical cell, modeled between the high voltage and the ground electrode, which shows pore formation possibility. Dimensions of the electrodes are maintained in mm and cm suitable for laboratory scale, continuous pulsed electric field treatments. In both the designs, emphasis is on the simulation to achieve higher electric field application in the inactivation area, which can be realized through satisfying electroporation phenomenon. From the observed results, it is understood that greater electric field application is achievable even using small efficient electrode designs, which in turn assures i) A greater bacterial inactivation in the liquid food and ii) A compact pulsed electric field experimental prototype.

Published

2016

35. THERMAL MODELS FOR A 3 CM MINIATURE XENON ION THRUSTER

Author

Coleman Thomas Younger

Subjects

Physics, Ion thruster, business.industry, Analytical chemistry, chemistry.chemical_element, Electrostatic ion thruster, Cold gas thruster, Xenon, Electrically powered spacecraft propulsion, chemistry, Field-emission electric propulsion, Colloid thruster, Pulsed inductive thruster, Aerospace engineering, business

Published

2016

36. Research on DC electric field measurement considering ion flow near HVDC transmission line

Author

Kaitian Huang, Zhanqing Yu, Bo Zhang, Jinliang He, Rong Zeng, Bin Lou, Zhiye Gao, Zheyao Wang, Qing Ma, Min Li, and Lei Liu

Subjects

business.industry, Chemistry, Electric field, Field-emission electric propulsion, Electrical engineering, Field strength, Electric potential, Optical field, business, Electric flux, Excitation, Computational physics, Voltage

Abstract

Measuring electric field has a very wide range of applications in the power system, but for the ion field under the HVDC transmission lines, the current measurements are insufficient. In this paper, effects of interventional measurement, theoretical analysis, measuring programs are researched. Sensors in a Poisson field sense an electric field Ein, which consists of three parts. E0 is the origin electric field, E1 indicates the field generated by charges attached on the sensor, E2 represents the influence of the redistribution of ion flow after the sensor is put into the field. Based on multi-physics simulation, this paper figures out the effects of sensor's intervention through analysing the movement of charged particles and found that when the charging process is completed, there is a spherical region around the sensor where the charge density is zero, which is called the “empty zone”. This paper figures out the relationship between inside field and outside field. The electric field directly measured by the sensor kernel module can be approximately regarded as the sum of the space field which we aim to measure and the self-generated electric field of the charge accumulated on the metal shell of sensor's shell. A structure of two-MEMS-device is promoted to deal with the effect of the ion flow, and it could applied in the ion field or nominal electric field without ion flow and ignore the angular offsets of placing, according to the simulations.

Published

2016

37. The use of Interfacial Graphene to Carbon nanotube Point emitter for Field Emission Electric Propulsion

Author

Jeong Seok Lee, Yong Hyup Kim, Tae June Kang, and Dae Weon Kim

Subjects

Materials science, business.industry, Graphene, Nanotechnology, Carbon nanotube, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, law.invention, Carbon nanotube field-effect transistor, Carbon nanotube quantum dot, Condensed Matter::Materials Science, Field electron emission, law, Field-emission electric propulsion, Optoelectronics, business, Voltage, Common emitter

Abstract

Carbon nanotube are nanostructure with extraordinary field emission properties like high current density, low driving voltage and long time stability, because of their high electrical conductivity, high aspect ratio for geometrical field enhancement and superior thermal stability. But, there is some problem to mate metal and carbon nanotube, we have resolved this problem by using interfacial graphene. This approach takes advantage of superior electric and thermal conductivity between metal and carbon nanotube and shows superior performance compared to the existing field emitters. This result shows that such a carbon nanotube emitter in a stage where it can be used for Field Emission Electric Propulsion (FEEP).

Published

2012

38. Modelling of an Electromagnetic Space Propulsion System for Pulse Mode Operation

Author

S. Thanigaiarasu, S. Sarathkumar, and K. Periyannaswamy

Subjects

Magnetoplasmadymanic, Engineering, Ion thruster, Spacecraft propulsion, Specific impulse, business.industry, Simulink, Electric propulsion, General Medicine, Variable Specific Impulse Magnetoplasma Rocket, Lorentz force, Electrically powered spacecraft propulsion, Laser propulsion, Physics::Space Physics, Field-emission electric propulsion, thrust, Aerospace engineering, business, Catiya, Electromagnetic propulsion, plasma, Engineering(all)

Abstract

The chemical rocket propulsion has limitations while applied to space application, with respect to specific impulse, delta-v, volume and stored energy, which can be overcome by electric propulsion system. Among various type of Electric propulsion system, the electromagnetic propulsion has added advantages for many space applications. In this paper an electromagnetic propulsion system is considered known as Magnetoplasmadynamic thrusters (MPD). The MPD thrust works based on principle of Lorentz force.The thruster is modeled based on Paschen's Law and snow plow model to operate it in pulsed mode to generate instantaneous peak thrust. This model includes the designing of high-current power supply, ignition circuit, and electrodes. Simulations have been performed by considering all the parameters involved in the model. The design parameters are analyzed for optimum value to get maximum thrust force.

Published

2012

39. Qualifciation test series of the indium needle FEEP micro-propulsion system for LISA Pathfinder

Author

R. Killinger, L. Serafini, A. Polli, M. Jentsch, L. Ceruti, D. DiCara, N. Buldrini, Carsten Scharlemann, and Davide Nicolini

Subjects

Physics, business.industry, Gravitational wave, Aerospace Engineering, Mechanical engineering, Thrust, Propulsion, Pathfinder, Electrically powered spacecraft propulsion, Acceptance testing, Field-emission electric propulsion, Aerospace engineering, business, Power control

Abstract

The Laser Interferometer Space Antenna project (LISA) is a co-operative program between ESA and NASA to detect gravitational waves by measuring distortions in the space–time fabric. LISA Pathfinder is the precursor mission to LISA designed to validate the core technologies intended for LISA. One of the enabling technologies is the micro-propulsion system based on field emission thrusters necessary to achieve the uniquely stringent propulsion requirements. A consortium consisting of Astrium GmbH and the University of Applied Sciences Wiener Neustadt (formerly AIT) was commissioned by ESA to develop and qualify the micro-propulsion system based on the Indium Needle FEEP technology. Several successful tests have verified the proper Needle Field Emission Electric Propulsion (FEEP) operation and the thermal and mechanical design of subcomponents of the developed system. For all functional tests, the flight representative Power Control Unit developed by SELEX Galileo S.p.A (also responsible for the Micro-Propulsion Subsystem (MPS) development) was used. Measurements have shown the exceptional stability of the thruster. An acceptance test of one Thruster Cluster Assembly (TCA) over 3600 h has shown the stable long term operation of the developed system. During the acceptance test compliance to all the applicable requirements have been shown such as a thrust resolution of 0.1 μN, thrust range capability between 0 and 100 μN, thrust overshoot much lower than the required 0.3 μN+3% and many others. In particular important is the voltage stability of the thruster (±1% over the duration of the testing) and the confirmation of the very low thrust noise. Based on the acceptance test the lifetime of the thruster is expected to exceed 39,000 h generating a total impulse bit of 6300 Ns at an average thrust level of 50 μN. A flight representative qualification model of the Needle FEEP Cluster Assembly (DM1) equipped with one active TCA has performed a qualification program consisting of acceptance, vibration, shock, and thermal vacuum test. During the last test, the thermal vacuum test (TVT), a performance decrease was observed. According to a preliminary analysis, this performance decrease is not linked to the thermal conditions simulated in the TVT but might be rather linked to secondary effects of the TVT set-up.

Published

2011

40. Combustion of ethanol fuel droplet in vertical direct current electric field

Author

Michikata Kono, Osamu Imamura, Kiyotaka Yamashita, Shunsuke Nishida, Bo Chen, and Mitsuhiro Tsue

Subjects

Permittivity, Chemistry, Mechanical Engineering, General Chemical Engineering, Direct current, Analytical chemistry, Drift current, Electric discharge in gases, Physics::Fluid Dynamics, Electric field, Field-emission electric propulsion, Physics::Chemical Physics, Physical and Theoretical Chemistry, Electric current, Atomic physics, Voltage

Abstract

Flame is affected by an external electric field because it contains ions and electrons related to chemical reactions. On the other hand, the movement of ions and electrons affects the external electric field due to their charge. This paper reports the combustion experiments of ethanol droplets in vertical electric field with variable distance electrodes apparatus in order to discuss the change of the external electric field due to the existence of flame. From a one-dimensional steady-state analysis, if the electric field is changed spatially, its effect on combustion behavior is aligned with V 2 / L 3 and not V / L, where V is the applied voltage between electrodes, and L is distance between the electrodes. The droplet is burned between the two horizontal parallel electrodes. The flame deformation and the electric current are characterized by various electrode distances, and respectively, applied voltages. The vertical electric field induces a body force downwards on the flame. The flame deforms downward in the electric field because the electric body force counters the natural buoyancy. The relation between the applied voltage and electrode distance is investigated when the flame becomes vertically symmetrical and the results show that the deformation is the function of V / L 1.5 . This indicates that the change in the electric field should be considered to discuss the effect of an external electric field on combustion behavior. The experimental results are rearranged using e V 2 / L 3 where e is electric permittivity of air because its unit is N/m 3 and it considered to be the representative electric body force. Although its application is limited, qualitatively it can help to explain the experimental results of a droplet combustion. In addition, the degree of electron attachment to neutral molecules is discussed to interpret our experimental results.

Published

2011

41. Development of Electric and Chemical Microthrusters

Author

Carsten Scharlemann and Martin Tajmar

Subjects

Propellant, Engineering, Electrically powered spacecraft propulsion, business.industry, lcsh:Motor vehicles. Aeronautics. Astronautics, Field-emission electric propulsion, Aerospace Engineering, Thrust, Specific impulse, lcsh:TL1-4050, Aerospace engineering, Propulsion, business

Abstract

The increasing application of microsatellites (from 10 kg up to 100 kg) as well as CubeSats for a rising number of various missions demands the development of miniaturized propulsion systems. Fotec and The University of Applied Sciences at Wiener Neustadt is developing a number of micropropulsion technologies including both electric and chemical thrusters targeting high performance at small scales. Our electric propulsion developments include a series of FEEP (field emission electric propulsion) thrusters, of which the thrust ranges fromμN to mN level. The thrusters are highly integrated into clusters of indium liquid-metal-ion sources that can provide ultralow thrust noise and long-term stability. We are also developing a micro PPT thruster that enables pointing capabilities for CubeSats. For chemical thrusters, we are developing novel micromonopropellant thrusters with several hundred mN as well as a 1–3 N bipropellant microrocket engine using green propellants and high specific impulse performance. This paper will give an overview of our micropropulsion developments at Fotec, highlighting performance as well as possible applications.

Published

2011

42. Effect of Electrode Distance on Combustion Behavior of Fuel Droplet in Vertical DC Electric Field

Author

Michikata Kono, Mitsuhiro Tsue, Kiyotaka Yamashita, Osamu Imamura, Shunsuke Nishida, and Bo Chen

Subjects

Materials science, business.industry, Diffusion flame, Electrical engineering, Combustion, Electric discharge in gases, Physics::Fluid Dynamics, Ion wind, Electric field, Field-emission electric propulsion, Physics::Chemical Physics, Electric current, Atomic physics, business, Voltage

Abstract

Flames are affected by external electric fields because they contain ions and electrons. The movement of ions and electrons affects the external electric field owing to their charge. In this context, this paper discusses the change in the electric field on the basis of experimental results obtained at different electrode distances. Employing one-dimensional (1D) steady-state analysis, we assume that if the electric field is changed spatially, the effect of the electric field on combustion behavior is aligned with V2/L3, where V is the applied voltage between the electrodes and L is the distance between the electrodes. Because a flame deforms to a cathode owing to electric body force in an electric field, the change in the flame shape of burning ethanol droplets observed in a vertical DC electric field and the electric current during combustion are measured as flame characteristics. The results reveal that applied electric voltage exists where the flame becomes vertically symmetrical to balance the buoyancy due to the electric body force. The relationship between m and n of Vm/Ln for flame symmetry is around n/m = 1.5. On the basis of these results, all experimental results for different electrode distances are rearranged with eV2/L3, which is a representative electric body force, and it is proved that the use of parameter eV2/L is effective. These results indicate that the change in the electric field due to the existence of a flame should be considered when examining the effect of an external electric field on combustion behavior.

Published

2011

43. Minimum emission current of indium‐field emission electric propulsion thruster

Author

Zhao Wansheng, Kang Xiao-ming, and Duan Junyi

Subjects

Physics, Liquid metal, business.industry, Electrical engineering, chemistry.chemical_element, General Medicine, Ion, chemistry, Electrically powered spacecraft propulsion, Field-emission electric propulsion, Gallium, Aerospace engineering, Electric current, Current (fluid), business, Indium

Abstract

PurposeField emission electric propulsion (FEEP) thruster is a type of electric propulsion based on space‐proven indium liquid metal ion sources. The lifetime of FEEP thruster limits its application in space. A better method to improve its lifetime is the reduction of emission current. This paper aims to discuss the minimum emission current of operating FEEP thrusters.Design/methodology/approachIn this work, theoretical models, including fluid‐flow model and ion formation model, are analyzed. Current densities of these models are discussed and the minimum emission current is calculated.FindingsThere are few equilibrium states under low emission current conditions. However, the minimum emission current is the only stable state at which the FEEP thruster can operate.Research limitations/implicationsThis analysis is mainly based on the needle indium FEEP, which is compared indirectly with experiments of gallium.Practical implicationsThis paper attempts to help designers choose appropriate electric parameters to improve the lifetime of FEEP.Originality/valueBy introducing and analyzing theoretical models, this paper calculates the minimum emission current for stable operation of FEEP.

Published

2010

44. Numerical Rebuilding of SMART-1 Hall Effect Thruster Plasma Plume

Author

L. Biagioni, Andrea Passaro, A. Vicini, and F. Nania

Subjects

Engineering, Spacecraft, Computer simulation, business.industry, Mechanical Engineering, Photovoltaic system, Aerospace Engineering, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Fuel Technology, Electrically powered spacecraft propulsion, Space and Planetary Science, Field-emission electric propulsion, Orbit (dynamics), Satellite, Aerospace engineering, business, Magnetoplasmadynamic thruster

Abstract

The SMART-1 flight data provided an excellent opportunity for extending validation of plume prediction codes to actual flight conditions. This paper will present the results obtained for the numerical simulation of the SMART-1 plasma plume using the PICPluS particle in cell code, which had been previously validated using ground experiment data. This activity can be considered as the first important step in the direction of a full in-flight validation for the code models and algorithms. A description of the implemented physical models is provided, followed by simulation results of experimental data from Alta's tests and from the literature. Finally, the results of the code application to the SMART-1 mission are presented, focusing on the simulation of retarding potential analyzer measurement, spacecraft floating potential, and interaction of the plasma field with the satellite (in particular the solar array). The results show that, although the possibility of dangerous interaction between the electric propulsion system and the spacecraft is very limited, a number of complex phenomena arise due to the use of the electric propulsion system in orbit. For example, the interaction between the plume and the solar array orientation leads to complex patterns for the spacecraft floating potential. Eventually, full three-dimensional simulation is therefore needed to accurately model this kind of phenomena with a realistic description of the involved geometries.

Published

2010

45. Study on the Relation Between Discharge Voltage and Magnetic Field Topography in a Hall Thruster Discharge Channel

Author

Daren Yu, Huanyu Liu, Junjing Li, Yuhai Li, and Zhongxi Ning

Subjects

Nuclear magnetic resonance, Materials science, Ion beam, Physics::Plasma Physics, Electric field, Field-emission electric propulsion, Pulsed inductive thruster, Plasma, Electric potential, Atomic physics, Condensed Matter Physics, Magnetic field, Voltage

Abstract

The relation between magnetic field topography and operating voltage is investigated in a 1kW Hall thruster discharge channel in order to focus the ion beam effectively and optimize the performance. The curvature of magnetic field line (α) is introduced to characterize the differences of topologies. The optimized magnetic field distribution under each operating voltage is obtained by experiment. Through the curvature transformation, we find that the area of (α > 1) in the channel gradually decreases with the increase of the operating voltage. In response to the results above, two dimensional plasma flows are simulated employing Particle-in-Cell method. The distributions of the electric potential, ion density and ion radial velocity are calculated to understand the important influence of the relation above on ion beam focusing. The numerical results indicate that magnetic field curvature and thermal electric field control the ion beam in the ionization and acceleration zone, respectively. The magnetic field topography and discharge voltage interact with each other and together form the focusing electric field. The ion radial mobility is suppressed effectively and the ion beam is focused to the channel centerline. In addition, for a given voltages, when the area of (α > 1) is larger than the optimal scope, the electric potential lines excessively bend to the anode causing ion over focus; contrarily, the electric potential lines will bend to the exit and defocus ions. All these results suggest the relation between magnetic field topography and discharge voltage is important to the ion radial flow control and performance optimization of the Hall thruster (© 2009 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim)

Published

2009

46. Regenerable Field Emission Cathode for Spacecraft Neutralization

Author

Jason M. Makela, Robert L. Washeleski, and Lyon B. King

Subjects

Materials science, business.industry, Mechanical Engineering, Aerospace Engineering, Nanotechnology, Ion current, Focused ion beam, Cathode, Ion source, law.invention, Taylor cone, Ion, Fuel Technology, Space and Planetary Science, law, Field-emission electric propulsion, Optoelectronics, business, Common emitter

Abstract

This research investigates the discharge characteristics of a field emission cathode for use in electric propulsion that has the ability to be regenerated when the emitter tip becomes damaged. Emitter tip regeneration is achieved by taking advantage of Taylor cone formation from an operating liquid―metal ion source. Tip formation is accomplished by solidifying, or quenching, the ion-emitting cone to preserve the sharp protrusion so that it can then be used for electron emission. Electron emission I-V curves were taken after tips were formed by quenching the liquid―metal ion source at ion discharge currents ranging from 1 to 25 μA. Fowler―Nordheim modeling was then used to estimate the emitter tip radii of each quenched liquid―metal ion source. Results of the Fowler―Nordheim modeling were promising, showing the ability to regenerate tips and to control the features of the resulting tips by varying the ion current during the quench process. The set of experiments that are reported demonstrated the regeneration process of emitter tip radii ranging from approximately 30―45 nm from a tip quenched at 2 μA down to tip radii of 15―22 nm when quenched at 25 μA.

Published

2009

47. Electric propulsion plasma plume interaction with 'Phobos-Soil' spacecraft structural components

Author

Vladimir A. Obukhov, G. A. Popov, and Andrey B. Nadiradze

Subjects

Materials science, Spacecraft propulsion, Ion thruster, Electrically powered spacecraft propulsion, business.industry, Laser propulsion, Field-emission electric propulsion, Aerospace Engineering, Variable Specific Impulse Magnetoplasma Rocket, Propulsion, Aerospace engineering, business, Plume

Abstract

Assessment was made by calculations for the possible consequences of the effect of plasma plume injected by the solar electric propulsion system (SEPS) on the structural components of “Phobos-Soil” spacecraft (SC). Propulsion system comprises three SPT-140 thrusters, two of which should secure the required total thrust impulse during 8000 hours of operation approximately. Variation of the solar panel (SP) properties as a result of their surface contamination with the products of erosion of thruster and SC structural components is the primary negative consequence of plasma plume effect on the SC. Calculation study for the processes of erosion, particle flow distribution, and contaminating coating formation on the SP surface was made for different SEPS arrangements. It is shown that power reduction for the landing module SP sections, which are subjected to the contaminating coating deposition to the most extent, will not exceed 5% of the nominal level.

Published

2009

48. High- and low-frequency noise in Cs and in liquid metal ion sources

Author

A. Genovese, F. Rüdenauer, and J. Mitterauer

Subjects

Physics, Oscillation, business.industry, Noise spectral density, Liquid metal ion source, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Optics, Noise generator, Field-emission electric propulsion, Flicker noise, business, Instrumentation, Electrical impedance, Noise (radio)

Abstract

Fundamental Physics space missions set rigid thrust noise limits for liquid metal ion thrusters used as actuators on drag-free platforms aboard the spacecraft. We have measured current-, voltage- and thrust noise of Cs and In LMIS, foreseen as prime candidates in these missions. In the high-frequency range, quasiperiodic oscillations around approximately 10(5)Hz can be observed for both types of emitters with frequency depending on emission current. In the low-frequency range (1-10(-3)Hz), which is particularly important for drag-free control, different types of noise events are observed, which in some instances show definite signs of deterministic chaos (period doubling, self-similarity). High-frequency current oscillations are generally ascribed to electro-hydrodynamic oscillations of the TAYLOR cone and the jet at its apex, with concomitant emission of charged nanodroplets. Comparison of theory and experiment shows unsatisfactory agreement in predicted vs. measured current oscillation frequencies and large disagreement in droplet emission frequencies. No theory is presently available for describing low-frequency noise events. In terms of a linearized Mair theory it is, however, shown that these noise events can be efficiently described by spontaneous variations in electrical emitter impedance. In spite of this impedance noise, the mission requirements for thrust noise (0.1microN/Hz(1/2)) can be met by a thrust-stabilized In emitter.

Published

2009

49. Formation of Charged Nanodroplets at Capillary Instability of the Liquid Emitter

Author

Ilgar I. Gurbanov and Ilkham S. Gasanov

Subjects

Liquid metal, Electrospray, Capillary wave, business.industry, Capillary action, Chemistry, General Engineering, General Physics and Astronomy, Ion current, Molecular physics, Ion source, Ion, Physics::Fluid Dynamics, Optics, Field-emission electric propulsion, business

Abstract

The fluctuation excitation mechanism and characteristics of fine dispersive phase in liquid metal ion sources were investigated. The system of standing capillary waves with frequencies of 2–30 MHz develops on the liquid surface during a droplet detachment from the top of the elongated Taylor's cone. The disturbance of a liquid surface modulates the extracting electric field and ion current, whose spectrum of fluctuations has the quasi discrete form. The spectrum of nanoparticle sizes is continuous because of their electrostatic instability upon disruption. The generated nanodroplets of 2–20 nm sizes can be used to coat thin films and create surface quantum structures. The constructed ion source with a penetrable porous electrode can be used to obtain nanoparticles from semiconductor materials. The working substance vapor appears locked inside the container owing to the penetration of the liquid inside the capillaries.

Published

2008

50. A Magnetically Enhanced Inductive Discharge Chamber for Electric Propulsion Applications

Author

Eric D. Gillman and John E. Foster

Subjects

Nuclear and High Energy Physics, Materials science, Electrically powered spacecraft propulsion, Ion thruster, Ambipolar diffusion, Field-emission electric propulsion, Ion current, Pulsed inductive thruster, Atomic physics, Condensed Matter Physics, Plasma processing, Ion source

Abstract

A magnetically enhanced inductive discharge was investigated for electric propulsion applications. The high plasma density produced by the source makes it attractive as an ion source for a gridded ion thruster or possibly a standalone ambipolar thruster. The discharge plasma is produced by a compact ldquostovetoprdquo spiral antenna that is similar to that used in plasma processing sources. Operation on argon to pressures as low as 1 mtorr was demonstrated at powers ranging from 100 to 250 W. Ion current as high as 1 A was extracted from a 10-cm-diameter device. Plasma properties and ion production efficiency are reported and commented upon.

Published

2008