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Notes From 3rd Annual Space Elevator Conference

Posted by timothy on from the don't-let-dennis-hopper-near-it dept.

colonist writes "The Space Elevator: 3rd Annual International Conference was held recently. Blaise Gassend, a PhD student at MIT, took notes. The main obstacle is still the material: transferring the strength of the nanotube to the ribbon. Other topics include: the nanotube tether Centennial Challenge; Elevator 2010, a challenge for a 250 kg climber to climb a 16 km tether; objections and refinements to Bradley Edwards' design; non-equatorial space elevators; replacing the term 'space elevator' with 'space bridge'; testing the space elevator material on cable cars; science; defense and economics."

10 of 469 comments (clear)

  1. Frontiers of Construction by feilkin · · Score: 5, Interesting

    I think that it should be taken into consideration that almost every major project of construction was deemed impossible. Very good examples of these are the famous Golden Gate Bridge and the EuroTunnel. Everyone said it was impossible, yet they were completed. As technologoy in this area continues to develop, I think that this may be able to become a real and practical idea sometime down the road. It may not be possible now, but in ten years, who knows?

  2. Alternative names for 'space elevator' by colonist · · Score: 4, Interesting

    Blaise Gassend's page mentions Andrew Price's list of alternative names:

    space bridge
    space way
    space rail

    'Space bridge' got the most approval from the audience.

    1. Re:Alternative names for 'space elevator' by dsmalle · · Score: 4, Interesting

      Heinlein called it "The Beanstalk"

  3. The Sailor's Rope Rule by TheTXLibra · · Score: 5, Interesting

    Forgive my ignorance, MEMS and Nanotech has fascinated me for a while, but I don't know enough of the math behind them to tell if this is true. My grandfather, rest his soul, once told me of something called the Sailor's Rope Rule, which effectively says that the weight a rope can support is diminished by its length. Thus, a 500 lb. rope might support 500 lbs when there's less than a foot or so in length between the pully and the weight, but might only support 250 lbs when there is a good 100 ft. or so... The actual support degradation of course depends upon the width of the rope and the material the rope is made of.

    So what I'm wondering is, does the same apply to the weight supported by nanotubes and other molecular chains. I figure it has to be less of a degradation due to the ionic bonds involved, but it would seem to me that, unless some Quantum rule is involved dealing with extremely small-scale weight supporting chains, that they might never overcome this problem due to the sheer thinness of the tubes, chains, etc. It might be extremely strong material, but if it's width is only a few atoms wide, wouldn't this material be, at least in single lengths, more or less useless by the time it got to a respectable length? This is, of course, excluding bundles, which make the most sense, I'm really just curious if the same rule applies to nanotubes as applies to rope.

    --
    -The Libra
    "Please be patient--The future will begin momentarily."
  4. Elevator:2010 information by colonist · · Score: 4, Interesting

    The Spaceward Foundation is creating the Elevator:2010 program:

    Our first program, Elevator:2010, is a public challenge centered around the Space Elevator concept, offering a substantial prize for the first laser-powered tether climbing demonstration that can meet a specific criteria.
    The challenge is intended to be difficult (hence the 2010 deadline) and physically impressive - using a several miles high balloon-suspended tether, and a beamed-power system larger than has been built to date.
    Around this challenge, we intend to create a comprehensive program with significant presence at technology and science museums, as well as public events (such as fairs and air shows), featuring smaller-scale displays and competitions, and allowing for individual hands-on participation at all levels, from high-school teams to private enthusiasts.
  5. Feasibility of the Space Elevator. by Dissectional · · Score: 5, Interesting

    I recall Arthur Clarke pitching the initial concept for a Space Elevator some time back, and revisited the idea in 3001 : The Final Odyssey - in which he depicted planet Earth having a fully functional ( four actually ) space elevator system; which facilitated a subset of human civilisation living in low earth orbits in reduced gravity - thus invoking presumed benefits of doing so.

    Anywho. He spoke a couple years ago, subsequent to 3001's release on how at the time of writing, such a feat was nigh on impossible at this stage - as the materials to construct the 'elevator' were yet to be developed. Until now. The carbon molecule Buckminsterfullerene ( C60 ), also known as 'Fullerene', is supposedly strong enough to actually make such a concept a reality - which is in part the reason the space elevator was hurled back into the limelight of late.

    I think its a fascinating idea - which until we develop propulsion systems beyond the primative scope of the 1,000+ year old firecracker concept, certainly seems a more elegant way for the species to venture into Space more regulary. Or, at the very least, be the catalyst for what could perhaps become the initial stepping stones to establishing a permanent presence in space which will hopefully later lead to space initiated launches.

  6. Re:Sadly, Too big a Terrorist Target. by joe_bruin · · Score: 4, Interesting

    you're forgetting the big upside of the space elevator: the owners of the space elevator can drop shit on you from space! heavy things like big rocks, kitchen sinks, and 2000 pound gps-guided bombs. and let it be clear, there is no defence against kitchen sinks falling on you from space. we're talking afforable space based weapons platforms. the weapon of choice of the future may be raindrop-shaped ceramic projectiles with spent-uranium cores, raining unstoppably from above and smashing their way through tanks and into underground bunkers, or sinking an aircraft carrier battlegroup.

    the military of the country that builds this wonderous weapons platform will let see to the safety of the tether, you can bet on that.

  7. Re:What provides the orbital speed of the cargo? by MetaMarty · · Score: 3, Interesting

    But is it really that less wasteful? Launching into orbit takes energy in 3 forms:
    - Gaining altitude: You still need the same energy in the space elevator
    - Gaining orbital speed: This will have to be compensated by propulsion at the top of the elevator, but is also the same as in a regular loss.
    - Atmospheric drag: This will be less because the cargo can move slower than a rocket. But still, must of the dynamic pressure experienced in a rocket is during the first minute of launch. After this, there's not much left.

    I guess most of the energy during conventional launch is lost because propellant has to be carried up. However, I think you will still need a fair amount of propellant at the top of the elevator to compensate for the loss of speed due to cargo being lifted up. This propellant somehow has to be transported up too, costing a lot of propellent itself. So will this really be much less wasteful?

  8. Re:What provides the orbital speed of the cargo? by Firethorn · · Score: 3, Interesting

    Simple enough to fix, you set the center of mass of the system, unloaded, to be slightly outside of geosync. That means that the system wants to fly off, but you keep running mass up to counteract the effect. If you don't want to run something up at the moment, you simply tie the tether down with a mass at the bottom, such as the oil type platform they propose.

    --
    I don't read AC A human right
  9. Rotovator(tm) by Baldrson · · Score: 4, Interesting
    Hans Moravec's Rotovator(tm) picks up hypersonic (near mach 12) payloads from an altitude of 100km and slings them to orbit.

    Current proposals for implementation of the Hans Moravec's original design rely on a hypersonic air-breather of advanced aerodynamic design like the Boeing DF-9 (that exists only on paper).

    Can /. readers think of anything likely come along in the near future that could take paylods to 100km and mach 12?

    Probably the same thing that is driving the bureaucrats to make all this noise about space elevators now.

    A key to the Rotovator(tm) is getting hub mass in place to keep it out of the atmosphere while it picks up mass from 100km@mach12 -- but that mass can be any old space junk -- at least at the hub where it counts the most for high strength materials like carbon nanotubes. However, you can do a Rotovator(tm) with off-the-shelf commercially available fibers and still have a factor of 2.

    Nice thing about Rotovators(tm) is that they can be built with much lower capitaliztion over a much shorter period of time using existing commercial materials. All you need is a bunch of mass orbiting near earth, some quite-doable tethers, and sufficient manuverability and speed in the atmospheric leg to hook up with the tether as it reaches the nadir.

    --
    Seastead this.