Electromagnetic Propulsion System for Spacecraft using Geomagnetic Fields and Superconductors

Dadhich, Anang

07 June 2016

No description available.

Aerospace Materials

Electromagnetic Propulsion

Superconductivity

Cryogenics

Spacecraft

Satellite

Spacecraft Propulsion

Estudo do efeito magnetohidrodinâmico em um eletrólito a partir do uso de um dispositivo ejetor eletromagnético / Study of MHD effect on an electrolyte solution, using an electromagnetic ejector device

Aoki, Luciano Pires

18 July 2011

A magnetohidrodinâmica, ou simplesmente MHD, é um campo da ciência que estuda os movimentos de fluidos condutores submetidos a forças eletromagnéticas e une conceitos da fluidodinâmica e eletromagnetismo. Nos últimos anos, a MHD vem sendo aplicada em diversas áreas tecnológicas, desde a propulsão eletromagnética até dispositivos biológicos. Neste trabalho, são mostradas a construção e a operação de um dispositivo MHD, um canal retangular preenchido com um fluido eletrolítico conhecido como macrobomba, isento de partes mecânicas móveis. Os imãs geram um campo magnético externo e os eletrodos criam um campo elétrico, perpendicular ao escoamento, que move o fluido. O modelo MHD é calculado a partir das equações de Navier Stokes acopladas às equações de Maxwell para um fluido incompressível newtoniano. As forças eletromagnéticas que surgem resultam do produto vetorial da densidade de corrente e da densidade de fluxo magnético - essa é a força de Lorentz. Os resultados são apresentados em simulações 3D numéricas, assim como em dados experimentais. O objetivo é relacionar o campo magnético com o elétrico e com a quantidade de movimento produzida, e calcular a densidade de corrente e o perfil de pressão e de velocidade. Um perfil U e M de pressões e velocidades é esperado no experimento. Dados experimentais e computacionais são comparados para validação e posterior uso para futuros trabalhos. / Magnetohydrodynamics or simply (MHD) is a field of science that studies the movement of conductive fluids subjected to electromagnetic forces. Such a phenomenon brings together concepts of fluid dynamics and electromagnetism. Over the years, MHD has been encountered in a wide area of technological applications electromagnetic propulsion to biological devices. The present work didactically shows the construction (materials and equipment) and operation of an MHD device; a rectangular closed circuit filled with an electrolyte fluid, known as macro pumps, where a permanent magnet generates a magnetic field and electrodes generate the electric field, perpendicular to the flow, moving the fluid. The MHD model has been derived from the Navier-Stokes equation and coupled with the Maxwell equations for Newtonian incompressible fluid. Electric and magnetic components engaged in the test chamber assist in creating the propulsion of the electrolyte fluid. The electromagnetic forces that arise are due to the cross product between the vector density of current and the vector density of magnetic field applied. This is the Lorentz force. Results are present of 3D numerical MHD simulation for Newtonian fluid as well as experimental data. The goal is to relate the magnetic field with the electric field and the amounts of movement produced, and calculate de current density and fluid´s pressure and velocity. An u-shaped and m-shaped velocity and pressure profiles are expected in the experiment. Computational and experimental data are compared for validation and future analysis.

Electromagnetic forces

Electromagnetic propulsion

Forças eletromagnéticas

Macro bomba

Macropumps

MHD

MHD

Propulsão eletromagnética

Estudo do efeito magnetohidrodinâmico em um eletrólito a partir do uso de um dispositivo ejetor eletromagnético / Study of MHD effect on an electrolyte solution, using an electromagnetic ejector device

Luciano Pires Aoki

18 July 2011

A magnetohidrodinâmica, ou simplesmente MHD, é um campo da ciência que estuda os movimentos de fluidos condutores submetidos a forças eletromagnéticas e une conceitos da fluidodinâmica e eletromagnetismo. Nos últimos anos, a MHD vem sendo aplicada em diversas áreas tecnológicas, desde a propulsão eletromagnética até dispositivos biológicos. Neste trabalho, são mostradas a construção e a operação de um dispositivo MHD, um canal retangular preenchido com um fluido eletrolítico conhecido como macrobomba, isento de partes mecânicas móveis. Os imãs geram um campo magnético externo e os eletrodos criam um campo elétrico, perpendicular ao escoamento, que move o fluido. O modelo MHD é calculado a partir das equações de Navier Stokes acopladas às equações de Maxwell para um fluido incompressível newtoniano. As forças eletromagnéticas que surgem resultam do produto vetorial da densidade de corrente e da densidade de fluxo magnético - essa é a força de Lorentz. Os resultados são apresentados em simulações 3D numéricas, assim como em dados experimentais. O objetivo é relacionar o campo magnético com o elétrico e com a quantidade de movimento produzida, e calcular a densidade de corrente e o perfil de pressão e de velocidade. Um perfil U e M de pressões e velocidades é esperado no experimento. Dados experimentais e computacionais são comparados para validação e posterior uso para futuros trabalhos. / Magnetohydrodynamics or simply (MHD) is a field of science that studies the movement of conductive fluids subjected to electromagnetic forces. Such a phenomenon brings together concepts of fluid dynamics and electromagnetism. Over the years, MHD has been encountered in a wide area of technological applications electromagnetic propulsion to biological devices. The present work didactically shows the construction (materials and equipment) and operation of an MHD device; a rectangular closed circuit filled with an electrolyte fluid, known as macro pumps, where a permanent magnet generates a magnetic field and electrodes generate the electric field, perpendicular to the flow, moving the fluid. The MHD model has been derived from the Navier-Stokes equation and coupled with the Maxwell equations for Newtonian incompressible fluid. Electric and magnetic components engaged in the test chamber assist in creating the propulsion of the electrolyte fluid. The electromagnetic forces that arise are due to the cross product between the vector density of current and the vector density of magnetic field applied. This is the Lorentz force. Results are present of 3D numerical MHD simulation for Newtonian fluid as well as experimental data. The goal is to relate the magnetic field with the electric field and the amounts of movement produced, and calculate de current density and fluid´s pressure and velocity. An u-shaped and m-shaped velocity and pressure profiles are expected in the experiment. Computational and experimental data are compared for validation and future analysis.

Forças eletromagnéticas

Macro bomba

MHD

Propulsão eletromagnética

Electromagnetic forces

Electromagnetic propulsion

Macropumps

MHD

Elektromagnetické výkonové aktuátory / Electromagnetic power actuators

Kadlecová, Lucie

January 2018

This master thesis focuses on literature research of problematics linked to power actuators working on electromagnetic principle to accelerate metal projectiles. It’s goal is mathematical analysis and constuction of selected type of electromagntic power actuator – induction coilgun

Elektromagnetické výkonové aktuátory / Electromagnetic power actuators

Kadlecová, Lucie

January 2018

This master thesis focuses on literature research of problematics linked to power actuators working on electromagnetic principle to accelerate metal projectiles. It’s goal is mathematical analysis and constuction of selected type of electromagntic power actuator – induction coilgun

Development and Testing of a Low-Current Applied-Field Magnetoplasmadynamic Thruster with a Rectangular Discharge Channel

Gondol, Norman, Tajmar, Martin

26 February 2024

This study explores the possibility of miniaturizing magnetoplasmadynamic thrusters (MPDTs) to significantly lower power and discharge current levels compared to most conventional MPDTs. A design alternative for MPDTs using a discharge channel with a rectangular cross-section is presented that enables the implementation of strong external magnetic fields to increase the applied-field Lorentz force. The thruster concept uses heaterless calcium aluminate electride (C12A7:e-) hollow cathodes as the electron source. A prototype of the concept intended for the low-amp current range generates thrust in the low millinewton range with a specific impulse ranging between 400 s and 1200 s at power levels below 500 W but shows high thermal power losses to the anode. A further miniaturized version of the concept intended for the sub-amp current range is thermally more sustainable but requires high mass flow rates to achieve a stable discharge, limiting the achievable specific impulse.

info:eu-repo/classification/ddc/600

ddc:600

Experimental investigation of electric propulsion systems using C12A7 electride hollow cathodes

Gondol, Norman, Tajmar, Martin

04 April 2024

The development and experimental investigation of two low-power electric propulsion concepts using compact heaterless C12A7 electride (C12A7:e-) hollow cathodes is presented. The first concept represents an electrothermal thruster, in which a cathode discharge is used to heat a gas that is subsequently accelerated in a nozzle-shaped anode. The second propulsion system is an attempt to develop a sub-500 W magnetoplasmadynamic thruster (MPDT) that uses a rectangular discharge channel that allows to increase the applied magnetic field and thus lower the necessary discharge current. Extensive parameter studies with both concepts were conducted, and the thrust and discharge properties of different geometric and operational configurations were determined. This work is a follow-up publication of a previous paper (Gondol and Tajmar in CEAS Space J 14:65–77, 2021).

info:eu-repo/classification/ddc/620

ddc:620