Space access

From Marspedia
Revision as of 12:21, 16 February 2009 by Rfc (talk | contribs) (moved details from Luna-Mars Trade to here)
Jump to: navigation, search

If colonists are to have access to space, they will need a craft to transport them.


Requirements

The craft should be:


SSTO

the craft should have SSTO capability. It has proved very difficult to build an SSTO launcher on Earth, but the lower Martian gravity would be of assistance to any launching spacecraft. If the craft uses multiple stages, these will all have to be recovered separately, which complicates the process of reuse.


Propellant

Hydrogen and oxygen propellants can be obtained from Martian ice. The attitude control thrusters could use gaseous oxygen and methane, kept under pressure.


Early landers

Early landers will probably be non-reusable or only partially reusable. The decent stages of these landers could be dismantled and reused.


Guidance

The guidance systems on the lander need not be hi-tech. The Apollo spacecraft flew to the Moon using less computing power then a pocket calculator. A simple computer, or a pneumatic system could be used. Although there are advantages with hi-tech systems, lo-tech systems could be included as a backup.

Uses

Uses for the lander include: Trips to Low Mars Orbit and possible space stations residing there, Trips to Phobos and Deimos Trips to ferry crews to and from space craft that have arrived from, or are headed for, Earth, or other planets. Possible satellite repair, not a dissimilar task as to what was imagined for the space shuttle in the 1970's

Shuttle

The cost of lifting items from Mars could become considerably less than the cost of lifting them from Earth. Low Mars orbit, at an altitude of 100 miles, has a velocity of 3440 meters per second, less than half of the velocity needed to orbit Earth at that altitude, more than twice the velocity needed to orbit Luna. With reusable rockets built on Earth to use liquid methane and liquid oxygen, if the exhaust velocity is 3500 meters per second, there should be 36% of the take-off weight in orbit. With wings for a supersonic in ground effect in the 0.1 psi Martian atmosphere, the empty weight should be held to 30% leaving 6% of the take-off weight as cargo. Practicality:

  • There seems reason to believe that supersonic in ground effect landing is a significant problem, and that it should yield to the proper effort, resulting in an economic Mars to Low Mars Orbit Shuttle (MTLMOS pronounced metal mos to rhyme with verbose). Donald Campbell was killed on the 4th of January, 1967 when the "Bluebird K7" racing boat flipped over and disintegrated at a speed greater than 300 mph. [1] The problem seems to have been longitudinal instability when high ground effect lifting forces acted on a center of lift that shifted rapidly with changing attitude.
  • This sort of problem is made more difficult by the need to consider the reflection of shock waves in supersonic flight in ground effect. Such problems were handled successfully when the "Thrust SSC" broke the speed of sound on land during a 15th of October 1997 setting of the world's land speed record. [2]
  • An ordinary wind tunnel by itself is insufficient for testing craft in supersonic ground effect conditions. A moving belt of caterpillar like treads on the bottom of the wind tunnel moving as fast as the gas in the wind tunnel could simulate the runway rushing past during landing. Having a belt of treads that are broad enough and move fast enough for the simulation would be expensive, but not as expensive as doing the testing on Mars. At least with only 0.1 psi of carbon dioxide needed for a simulation, it would not cost as much as otherwise to fill the wind tunnel with cold carbon dioxide.
  • Landing at a speed in the neighborhood of 1000 mph (mach 1.9 on Mars) might seem more difficult than the feat accomplished by "Thrust SSC," but moving through only 150th of the gas pressure (100th of the density) more than compensates for the increased speed. Maintaining lift and orientational stability are the problems for which we have aeronautical engineers, computational aerodynamics, and wind tunnels.

Space Elevator

A space elevator is an interesting alternative both for Luna and Mars. Probably, it allows even more cost reduction.


references

  1. Bluebird K7 article at Wikipedia
  2. http://www.speedace.info/thrust_ssc