passive propellant feeding in electrospray-ion microthrusters
TRANSCRIPT
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Passive Propellant Feeding in Electrospray-Ion Microthrusters
D. Courtney, S. Dandavino, S. Chakraborty and H. Shea
Microsystems for Space Technologies Laboratory (LMTS)
lmts.epfl.chhttp://lmts.epfl.ch/MEMS-ion-source
EPFL, Switzerland
9th ESA Round Table on Micro and Nano Technologies for Space Applications, Lausanne • Switzerland, June 12-15, 2014
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Electric propulsion for in-space maneuvers
9th ESA Round Table on Micro and Nano Technologies for Space
Applications, Lausanne • Switzerland2
Low thrust propulsion systems
In-space orbital maneuvers
Station keeping
Attitude control
Low system mass/size is enabling
ESA Artemis
JAXA Hayabusa
6/12/2014
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Propellant-efficient electric propulsion
9th ESA Round Table on Micro and Nano Technologies for Space
Applications, Lausanne • Switzerland3
Increasing exhaust velocity (specific impulse) : More Payload, Less Propellant
ElectrostaticBi-propellantCold-gasEADS AstriumEADS Astrium
MIT
Spacecraft
mass
Payload
Propellant
6/12/2014
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Propellant-efficient electric propulsion
9th ESA Round Table on Micro and Nano Technologies for Space
Applications, Lausanne • Switzerland4
Increasing exhaust velocity (specific impulse) : More Payload, Less Propellant
ElectrostaticBi-propellantCold-gasEADS AstriumEADS Astrium
MIT
Spacecraft
mass
Payload
Propellant
Electrostatic Propulsion : Ideally High specific impulse (Isp) and power efficiency (ƞ)
QinetiQ T5
19cm
Isp > 1800s
ƞ< ~10%Isp > 1500s
Ƞ> ~50% Miniaturize
Snecma
PPS 1350 Busek BFRIT-1
21cm
6/12/2014
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Propellant-efficient electric propulsion
9th ESA Round Table on Micro and Nano Technologies for Space
Applications, Lausanne • Switzerland5
Increasing exhaust velocity (specific impulse) : More Payload, Less Propellant
ElectrostaticBi-propellantCold-gasEADS AstriumEADS Astrium
MIT
Spacecraft
mass
Payload
Propellant
Electrostatic Propulsion : Ideally High specific impulse and power efficiency
QinetiQ T5
19cm
Isp > 1800s
ƞ< ~10%Isp > 1500s
Ƞ> ~50% Miniaturize
Snecma
PPS 1350 Busek BFRIT-1
21cm
Ionic liquid electrospray propulsionMicrofabricated electrospray emitter arrays
High propellant efficiency
High power efficiency
Within compact deviceFP7 MicroThrust
6/12/2014
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Ionic Liquid Electrospray PropulsionPresentation Overview1. Concept motivation:
Benefits of passively fed ionic liquid ion source thrusters
2. Technology status:FP7 MicroThrust Program, overview and results
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Purely ionic emission and passive propellant transport in electrospray propulsion
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Ion emission yields high beam velocities
Low propellant mass per mission
Purely ionic emission
Propellant and power efficient
V. low thrust per emitter, arrays are required
Targeted at EPFL through narrow
microfabricated emitters
Droplets Ionsv
V
Passive / Zero-G Compatible Feeding
Fluid transport by capillarity / wicking
Many system benefits (discussed here)
Limited demonstration to date
20µm 10µm
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Why passivize IL feeding?Simplicity
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Plasma (Hall/GIT) thrusters
High performance but difficult to
miniaturize systems
Propellant stored as gas (typically)
• Heavy storage tank
• Power, mass and volume consuming
valves
Discharge chamber
• On-orbit ionization
• Potentially complex
Positive beam emissions
• Require external neutralizer
• Resource and performance loss
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Simple
Passively fed IL-Electrospray
Propellant stored as liquid
• IL has zero vapour pressure
• Stored as liquid in vacuum
Passive feeding
• No valves or regulators
Solvent free ‘ionic liquid’
• Plasma in bottle, direct field emission
Bi-polar field emission
• Simultaneous +/- emissions neutralize
and contribute to thrust
Why passivize IL feeding?Simplicity
96/12/2014
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Spacecraft
w/ distributed thrusters
Simple
Geostationary SGDC satellite (aviationnews.eu)
Why passivize IL feeding?Scalability
6/12/2014
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Spacecraft
w/ distributed thrusters
Simple
Geostationary SGDC satellite (aviationnews.eu)
Orbit raising
Station keeping
Why passivize IL feeding?Scalability
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Spacecraft
w/ distributed thrusters
Simple
Geostationary SGDC satellite (aviationnews.eu)
Attitude control
Slew maneuvers
Why passivize IL feeding?Scalability
6/12/2014
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Spacecraft
w/ distributed thrusters
Shrink thruster :
Performance losses
Sub-systems not easily
miniaturized/distributed
Why passivize IL feeding? : Scalability of plasma EP
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Spacecraft
w/ distributed thrusters
Simple
Why passivize IL feeding? : Scalability of IL electrospray EP
6/12/2014
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Spacecraft
w/ distributed thrusters
Simple
Why passivize IL feeding? : Scalability of IL electrospray EP
6/12/2014
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Spacecraft
w/ distributed thrusters
Inherently miniature/scalable
No performance loss
Thrust/area approaching GITs
Modular / scalable Simple
Why passivize IL feeding? : Scalability of IL electrospray EP
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Positive / forced feeding
Modular / scalable Simple
Why passivize IL feeding? : Liquid shorts in pressure fed devices
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Positive / forced feeding
Modular / scalable Simple
Why passivize IL feeding? : Liquid shorts in pressure fed devices
6/12/2014
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Passive feeding
Modular / scalable Simple
Why passivize IL feeding? : Prevention of liquid shorts
“Negative” pressure
pulls liquid back to
original state
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Passive feeding
“Negative” pressure
pulls liquid back to
original state
Simple Modular / scalable Safe / reliable
Why passivize IL feeding? : Prevention of liquid shorts
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MicroThrust : An FP7 Project
MicroThrust: Electrospray propulsion system for small spacecraft
Microfabricated arrays of IL electrospray• Up 127 emitters per array in first phase
Complete module (concept):• Wet mass: < 300g / kg of launch (30%)• Power: <5 W @ 3.5 kV• Dimensions: < 10cm x 10cm x 10cm
• Isp: > 3000s• Thrust: 20 µN/W• ΔV: 5 km/s
Partners:• EPFL (Switzerland)• Queen Mary University of London (UK)• Nanospace (Sweden)• TNO (Netherlands) • SystematIC (Netherlands)
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MicroThrust applications : Mission analysis examples
Mission optimizations performedby partners : Swiss Space Center (EPFL)
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GTO to Lunar orbit mission
Enabled by MicroThrust high density fabrication
8 Emitter arrays,
2300 emitters per chip
Purely ionic emission
~2.5 year transit
~65% payload mass ratio
Clean Space One
Retrieve and de-orbit SwissCube
ΔV>~650m/s required
Enabled by MicroThrust high density fabrication
4 Emitter arrays,
~3000 per chip
Mixed ion/droplet mode
~85% payload mass fraction
6/12/2014
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MicroThrust results: Performance status and beam focusing capability
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Downstream beam focusing
With integrated extractor grid (next pres.)
Vaccel
Acceleration grid gives
Focusing
Improved power efficiency
and
Exhaust velocity control
Mission optimization
Many 10’s of µA from 127 emitter array
No saturation condition reached
Up to 95% ionic emission
Isp~1000s
Thrust levels up to ~7µN per chip
~30µN per MicroThrust breadboard
Measurements by
QMUL
‘Startup’
@~750V
Beam half angle (deg)
Cu
rre
nt (µ
A)
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Bi-Polar Emission:Removes external neutralizer and suppresses reactions
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Symmetric emission currents
Minimizes charge build up at
alternating potential
Continuous bi-polar operation for>4.5 hours
Missions will require >800 hours of operation
Typically failed due to fluid bridge:
To be addressed with passive feeding
70 140 210 280 Mins.
MicroThrust Results:Bi-polar operation for long durations
Polarity alternated
@ 0.2Hz
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Summary and Next Steps
• Ionic Liquid electrospray ion propulsion with passive feedingHigh propellant and power efficiency and:
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• MicroThrust (completed Dec. 2013)• Novel microfabricted emitters
• Integrated extraction and acceleration electrodes (details in following presentation)
• Promising preliminary performance measurements
• Next : A focus on fluid feeding• Expand hydraulic features of MicroThrust devices
(next presentation)
• New developments focused on reservoirs
• Study impact of upstream flow on performance Liquid
Ion Beams
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Thank You
26
Thank you to MicroThrust partners
SSC, QMUL, TNO, SystematIC, NanoSpace
MicroThrust was an EU-FP7 Program
Work currently supported by ESA-NPI #4000109063/13/NL/PA
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What is passive feeding?
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Active / Pressure Fed
Liquid forced through emitters
Liquid meniscus at positive pressure
Devices tend to operate in droplet or mixed
regime
No valves or active controls : Typically porous material
Liquid pulled into device due to “negative” pressure
Devices tend to operate in purely ionic regime
Passive/Capillarity Driven
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