2. Chemical
thrusters
• Chemical thrusters such as fuels can’t give much power for a long
mission
• Its is unreliable , that it needs frequent refueling
Solar energy
• Solar energy is abundantly available in space, but cant utilize it
completely
asteroids
• Fast moving shuttles are needed
• A sustainable energy conversion system have to find out
4. Efficient use of fuel and electrical power
enables modern space craft to travel more
Can provide higher spacecraft top speeds
than any other rocket currently available.
Cheaper and faster than any other
propulsion technology
5. What is an ion ?
• Ion is simply an atom or molecule that is
electrically charged
• Ionization is the process of charging an atom
• A gas is considered as ionized when some or all
atoms are converted to ion
• Plasma is known as the fourth state and in that
state gas is neutral
• It has the some properties of gas , but affected
with magnetic and electrical properties
6. • The mechanism uses charged particles to
propel aircrafts forward
• Operation relies on charge to mass ratio of
electrons
• Thomason's work with cathode ray tube
• A cathode filament in a chamber with inert
gases
How does it works?
7. • The gases are charged by filament
• Accelerated by the grid downstream
• Electrons are collected through a
tube
• The second grid accelerates the ion
to 35km/s^2
8. Layout of a thruster
Multi inlet
Propellant at three
corners
External source
Anodes placed in
walls
11. Xenon is an inert gas and thus
corrosion can be avoided
First Ionization energy of xenon is .125eV/atom
Have high charge to mass ratio. (7.14 x 10^5 coul/kg)
13. Electrostatic ion thrust
Hall effect thruster
High power electric propulsion
Dual stage 4- grid
Electrodeless plasma thruster
14. ELECTROSTATIC ION THRUST
Made by Hughes space division
Owned by Boeing corp.
Uses xenon ions
Acceleration of 30km/s
Ten times faster than chemical rockets
15. HALL EFFECT THRUSTER
Known as plasma thruster
Uses hall effect to capture
electron
Ionization
Soviet model was successful
No need of external energy source
16.
17.
18. Uses microwaves and magnetic field for
excitation
Effective for low changing density gases
to plasma
NASA believes by removing the cathode
and equalizer , mean life can increased
Projected to use in Jupiter missions .
Acceleration of 38km/s^2
19. Two stages of acceleration
Better throttling
Low wastage of energy
It can attain 210 km/s
It’s a contribution of European space
agency
Mission mars
Dual stage 4- grid
20. Similar to HET
EPT doesn’t have an electrode to collect electrons.
Reduces failure rate and there are no mechanical part in
the stream.
Because the ion is accelerated by magnetic field , no
neutralizer is used.
Energy needed for thruster is minimum
This increases efficiency up to 91%
21. •first design ion engines
at rear ends
•Maximum carriage of
people.
•Have a speed of
commercial
aircraft(approx 500-600
MPH)
22. More streamlined body
Ion thruster placed below
Solar panels are placed above the shuttle
Achievement of maximum solar power
The design allows more speed, but low
payloads
23. Use of liquid nitrogen
Passed through porous in to system
Cool down the tile and adhesives
We need to improve the techniques
New adhesives have to be implemented
Storage of liquid nitrogen.
24. Ion drive in some form or fashion will be the
future of space exploration.
It took 30 years for the development of idea
The new engine by nasa, says it can take
humans to mars in 39 days
Can think about vehicles in earth with ion
engine as a booster
27. ^ Electric Spacecraft Propulsion, Electric versus Chemical Propulsion, ESA Science & Technology
^ a b E. Y. Choueiri. "A Critical History of Electric Propulsion: The First 50 Years (1906–1956)".
Retrieved 2007-11-07.
^ Mark Wright, April 6, 1999, science.nasa.gov, Ion Propulsion 50 years in the making
^ "Robert H. Goddard: American Rocket Pioneer". Smithsonian Scrapbook. Smithsonian
Institution Archives. Retrieved 28 March 2012.
^ a b "Innovative Engines - Glenn Ion Propulsion Research Tames the Challenges of 21st
Century Space Travel". Retrieved 2007-11-19.
^ (Russian) "Native Electric Propulsion Engines Today" (7). Novosti Kosmonavtiki. 1999.
Archived from the original on 6 June 2011.
^ a b c d Shiga, David (2007-09-28). "Next-generation ion engine sets new thrust record".
NewScientist. Retrieved 2011-02-02.
^ "ESA and ANU make space propulsion breakthrough" (Press release). ESA. 2006-01-11.
Retrieved 2007-06-29.
^ ANU Space Plasma, Power & Propulsion Group (SP3) (2006-12-06). "ANU and ESA make space
propulsion breakthrough". DS4G Web Story. The Australian National University. Archived from
the original on 2007-06-27. Retrieved 2007-06-30.
^ Oleson, S. R., & Sankovic, J. M. "Advanced Hall Electric Propulsion for Future In-Space
Transportation". Retrieved 2007-11-21.
^ "FEEP - Field Emission Electric Propulsion". Retrieved 2012-04-27.
^ a b c Marcuccio, S., et al. "Experimental Performance of Field Emission Microthrusters".
Retrieved 2012-04-27.
^ ElectroHydroDynamic Thrusters (EHDT), RMCybernetics.
28. The Daily Galaxy: NASA Trumps Star Trek: Ion
Drive Live! (April 13, 2009)
The Daily Galaxy: The Ultimate Space Gadget:
NASA's Ion Drive Live! (July 7, 2009)
Mason, L. (2000, April). 4.5-kW Hall Effect
Thruster Evaluated. Retrieved December 13,
2006, from
http://www.grc.nasa.gov/WWW/RT1999/5000/5
430mason.html/Hall Effect. (2006, December
12). Retrieved December 13,2006, from
http://en.wikipedia.org/wiki/Hall_effectWhat's a
Hall Thruster?. (n.d.).