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Space Science

Highlift Systems' Space Elevator In The News Again 618

Kris_J writes "Highlift Systems may have found a second location for the anchor of their space elevator -- Perth, Western Australia. Apparently we have the calm waters and international airport that it needs, amongst other things. Slashdot has covered this company's efforts before: Oct 9, 2002 and, earlier, August 13, 2002, but it's worth discussing again since '[recent funding] has been given momentum by the Columbia shuttle disaster.'"
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Highlift Systems' Space Elevator In The News Again

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  • by hsidhu ( 184286 ) on Sunday February 16, 2003 @07:48PM (#5316241) Homepage
    you know some jack ass is going to press the buttons for floors 1 -100,000
  • by rela ( 531062 ) on Sunday February 16, 2003 @07:49PM (#5316242) Journal
    Once again I'll get modded flamebait for this, I'm sure, but will SOMEONE explain to me how such a thing is supposed to work? What is resisting the downward force of the elevator climbing the cable? What is bearing the load against the earth's gravity? Items in orbit are not nailed to the sky, after all, they're just falling around the earth in just the right way.
    • Re:Okay (Score:2, Informative)

      by w42w42 ( 538630 )
      Think of holding a string with a weight attached to the end of it. Now swing it around your head. The faster you swing, the more horizontal the string becomes. It's the same effect with this 'space elevator'. The idea is to have an asteroid or some other heavy body attached to the end of the space elevator, and as the earth *swings* it around, the force of that weight on the end is supposed to keep it in place.

      Obviously, there has to be a pretty good anchor in the ground for it not to go flying into space.
      • Re:Okay (Score:3, Interesting)

        "Obviously, there has to be a pretty good anchor in the ground for it not to go flying into space."

        Question: The article mentions having a cable some 100,000 kms long. Uh, wouldn't that lap the planet a few times? What would keep (or cause) a Gary Larsonesque tragedy from occuring?

        Granted I'm being leight hearted with my question, but in light of the recent shuttle tragedy one has to weigh the potential risk of something like this happening.
        • Re:Okay (Score:4, Insightful)

          by WolfWithoutAClause ( 162946 ) on Sunday February 16, 2003 @08:52PM (#5316487) Homepage
          It's self stabilising. If the cable goes slightly off the vertical, the rotation ('centrifugal force' if you like fictious forces) tends to pull the cable back above the fixing point; it's like a giant pendulum.
        • Re:Okay (Score:3, Informative)

          by Qzukk ( 229616 )
          Simple. Just like the shuttle did, it would burn up in the atmosphere and break up. Maybe the lower portion of it would have some explosives to blow it into little pieces if it ever came apart (since it wouldn't be high enough up to burn up), but this is part of why it would be ocean-based (then, if it did fall the only people upset would be the environmentalists)

          If this is built out of carbon nanotubes, like people suggest, then its possible they could be woven together in such a way that if any point broke, the chain would come apart in many places, so that a lot of little pieces would fall, however the extra length/weight of tubing required for this might make it prohibitive.
        • Re:Okay (Score:3, Interesting)

          by morn ( 136835 )
          Warning: Spoiler if you're planning to read Kim Stanley Robinson's 'Mars' trilogy.

          Something like this happens in 'Red Mars' - the cable snaps after the end-point in space is blown up, and wraps itself aroung the planet, with huge destructive force, making a giant trench. KSR prides himself on being as scientifically accurate as possible, is this an error?
          • Re:Okay (Score:3, Informative)

            by Eivind ( 15695 )
            Yeah. It's an error.

            The cable simply lacks the required strength to do this. It's made of carbon nanotubes, which are incredibly strong and ligthweigth. Those tubes would however burn up on reentry in the atmosphere.

            If some low pieces should somehow *not* burn up, then they would fall very slowly, this is due to the low density of such a cable. Think along the lines of a 5cm wide strip of paper falling. It would not make a huge mess on impact exactly...

      • by cybercuzco ( 100904 ) on Sunday February 16, 2003 @11:14PM (#5316993) Homepage Journal
        absolutely not true. the elevator is in orbit around the earth just like the moon or any other satellite. the center of gravity of the elevator is in geosynchronous orbit (36000 km or 6.6 ER) Geosynchronous orbit has an orbital period the same as the rotation rate of the earth. A geostationary earth has a period of 24 hours and coincides with one spot on the earths surface. In other words, anything in that orbit will remain over the exact same spot essentially forever. The elevator goes into a geostationary orbit. Since its long, they can put the cable down anywhere within a 45 degree arc. The only thing you need an anchor for is to keep track of the cable. The greatest tension on the cable is at its center of gravity, because at that point, half the cable above it is centripetally trying to be flung into space, and the other half is trying to fall down to the earth. But this is located in geostationary orbit. Theres little if any tension on the cable at ground level.
      • Re:Okay (Score:4, Informative)

        by ryanvm ( 247662 ) on Sunday February 16, 2003 @11:36PM (#5317107)
        Unfortunatly you are absolutely wrong. In the example you gave the object is held in "orbit" by the tether. That is most definitely NOT how space elevators work. If it were, "a pretty good anchor" would be something of an understatement. ; )

        This is a bit of a simplification, but here goes. In a space elevator, the object at the other end of the cable is in geosynchronous orbit. The cable's purpose is purely for the elevator to traverse. You could take the cable away and the object at the end would still be there*. It is not holding the object in it's orbit - that's what gravity is for.

        * Technically, that's not true. Because the cable and cargo have some weight, you have to figure it into the calculations on where the object at the end will rest. It will actually be slightly farther than geosynchronous orbit.
    • Re:Okay (Score:2, Insightful)

      by silvaran ( 214334 )
      What is bearing the load against the earth's gravity?

      Rotational velocity. The rotation of the earth imposes an outward force on the elevator, keeping it in place. The elevator would be anchored to the earth, not anchored to the sky.
      • Re:Okay (Score:3, Informative)

        by gilroy ( 155262 )
        Blockquoth the poster:


        What is bearing the load against the earth's gravity?

        Rotational velocity. The rotation of the earth imposes an outward force on the elevator, keeping it in place.

        What's that sound? Why, it's just Isaac Newton, spinning in his grave fast enough to power a city...


        Velocity exerts no force. The orbital anchor will "want" to fly off straight at high speed. The (currently wundertech) carbon nanotube cable, attached to it, suffers a tension. The Newton III complement to this tension pulls the anchor toward the Earth. This imparts an acceleration exactly balanced so as to cause the anchor to execute a circle about the center of the Earth.


        It's only been 320 years since the Principia. Maybe someday soon we'll catch up to Newton.

    • Re:Okay (Score:5, Informative)

      by Speare ( 84249 ) on Sunday February 16, 2003 @07:53PM (#5316259) Homepage Journal

      will SOMEONE explain to me how such a thing is supposed to work?

      In a nutshell, the center of mass of the whole elevator, including ribbon and cargo, is at (or near enough) the radius which provides geosynchronous orbit. This can be achieved and maintained in a number of ways, all of which are irrelevant details once you grok what 'geosynchrony' and 'orbit' really mean.

    • Re:Okay (Score:2, Informative)

      by xtal ( 49134 )
      The earth is spinning. At ~100miles, it's moving very, very, very fast. The centriptal force created by that motion will hold it out. I don't know the specific speeds and forces offhand, and I'm too lazy to get my physics text off the bookshelf.

      To give you an idea, get a weight and tie a rope to it. Spin in a circle. Notice the weight pulls away from you and stays steady? Now, you could build a little robot to move up and down that rope (while you are spinning it). That's how it works. The forces are astronomical though, and the materials science problem is why it hasn't been attempted before.
    • Re:Okay (Score:3, Informative)

      by jericho4.0 ( 565125 )
      Centrifugal force. The top end has a high angular velocity that pulls it away from the earth.

      The other possibility sometimes mentioned is electrical charge. The differential over a long length of conductor inserted into the Van Allen belt could provide enough charge to suspend it.

    • Re:Okay (Score:5, Informative)

      by Anonymous Coward on Sunday February 16, 2003 @07:57PM (#5316272)
      http://www.howstuffworks.com/space-elevator.htm
    • Re:Okay (Score:5, Informative)

      by op51n ( 544058 ) on Sunday February 16, 2003 @07:59PM (#5316281)
      Centrifugal force. I have the .pdf file, the examination on the plausability of this working. The cable would be 60,000 miles long. At this length the force of the Earth spinning would hold the end of the cable outwards in a straight line.
      The first cable would be 1 micron thick, and taper from 5cm wide at Earth to 11.5cm in space. This would be added to each climb. By the 107th addition it would be capable of holding a climber of 22tons with a 14 ton payload.
      Of course it would be made of Carbon nanotubes (the only thing that could possibly be strong enough and light enough).
      Now I'm not saying I believe it can or will be done. I'm only quoting Bradley C. Edward's paper.
      • Re:Okay (Score:5, Informative)

        by thebigmacd ( 545973 ) on Sunday February 16, 2003 @08:59PM (#5316510)
        There is NO SUCH THING as "centrifugal force". "Centrifugal force" is the effect of tension in a cable against the center of rotation caused by CENTRIPETAL force accelerating the swung object towards the center.
        It's like this...a car pulls a trailer. The car is pulling the trailer! There is a force acting backwards on the trailer hitch on the car, but it is actually the car pulling the trailer, not the other way around. The anchor is not pulled by the swung object, the anchor PULLS the swung object.
        If the string is cut, the object does not accelerate away from the anchor because of some centrifugal force; the object will STOP accelerating and continue along in a straight tangential line.
        Centripetal force is real, centrifugal force is apparent.
    • Re:Okay (Score:5, Funny)

      by Rubbersoul ( 199583 ) on Sunday February 16, 2003 @08:01PM (#5316288)
      See the world is round and Australia is at the bottom of it. So by putting it in Australia it can just kinda dangle off of earth into space (being that Australia is down under and all).

      I hope the clears it all up (or down as the case may be) for you.
    • Re:Okay (Score:3, Informative)

      by JebusIsLord ( 566856 )
      My guess is you have to put a weight on the end out just far enough away from geostationary orbit to counteract the downward forces.
    • Re:Okay (Score:3, Informative)

      by iabervon ( 1971 )
      The top end is actually above orbit, such that the center of inertia of the entire thing (elevator included) is in orbit (adjusting for the different gravity over the length of the cable, of course). So the real answer is that there is excess upwards force, but the end can't fly off because the cable holds it down. Then the elevator pulls against that force.
    • by QuantumG ( 50515 ) <qg@biodome.org> on Sunday February 16, 2003 @08:09PM (#5316317) Homepage Journal
      Simply read the docs [highliftsystems.com]:

      The simplest explanation of the space elevator is that it is a cable with one end attached to the Earth's surface and the other end in space beyond the geosynchronous orbit (35,800 km altitude). The competing forces of gravity at the lower end and outward centrifugal acceleration at the farther end keep the cable under tension and stationary over a single position on Earth. This cable, once deployed, can be ascended by mechanical means to Earth orbit.

      Which just goes to show, if you're asking on Slashdot, then you're either too lazy or too stupid to find out yourself.

    • Note you'll also need inertial dampeners to quell the dramatic speedups/slowdowns for mere mortals.
    • Re:Okay (Score:3, Insightful)

      by JWSmythe ( 446288 )
      It's the same force that keeps the moon in orbit without falling down on us..

      Centrifugal force pulls the moon away from us.

      Gravity (both from the Earth and Moon) pull them towards each other.

      Kind of like if you swing a weight on a string. But gravity is the string. That's why the moon can be not in a geosynchronous orbit. It's string moves. :)

      With a heavy weight (platform) on the end of their carbon nanotube string, far enough away from the Earth, the platform should be pulling on the string, so the fact that you're pulling a bit on the string back down isn't much.. You'd be as significant as an ant on top of a mountain. :)

      That'll be an interesting place to visit..

      I wonder how long after the build it, that someone will build a solar sail craft.. It's not a hard concept.. Make "sails" big enough to create a small force from the solar winds. Then it would be a simple matter of riding the winds and gravational forces of the bodies encountered. Mars may be a lot closer than we thought.. You could fly the solar system with almost no fuel. :)

      I volunteer to take a fast run to Pluto. The course should be pretty easy. It'll just take a little math to figure out..

      Leave the platform, "falling" towards the moon. Pass the moon, and change your vector towards the sun (ok, a little fuel). Now "fall" towards the sun.. It's a good sized object, it should have a little pull. (hehe).

      Use Venus and it's moons your next turning point. Sails out, then pick and choose your planets to use to manuver..

      With a bit of good navigation other solar systems aren't quite as unreachable as they are now..

    • Re:Okay (Score:4, Informative)

      by X-rated Ouroboros ( 526150 ) on Sunday February 16, 2003 @08:54PM (#5316492) Homepage

      Speare's giving the basic idea: You keep the entire Load-Cable-Station system as a whole at (or near) geosync.

      There are a couple different methods that have been tossed around, some more elegant or wasteful than others.

      One method involves building a massive offloading station and using rockets to automatically maintain the orbit. You basically ignore the orbital decay induced by lifting the elevator, as the load is probably much smaller than the space platform and won't have an effect the already necessary constant correction wouldn't take care of in it's normal course of duty. This method is relatively easy to initially set up, but lifting heavier loads would require A) more propellant AND/OR B) a more massive end station.

      Another plan is to have mobile weight(s) attached along the cable. As a load advances along the cable the weight(s) adjust position (and so the effect on the station-cable system's orbit) to counterbalance the drag of the load. Basically you turn the whole thing into a huge counter-beam balance. The really kinda groovy thing about this system is that you can automate the weights and skip the whole business of a far-end station altogether and just have the load slip off the end of the cable.

      A third option involves launching a counterweight into a higher orbit and then reeling it back in while the load is climbing.

      Incidentally, as seductively simple as the swing-a-rock-around-your-head description sounds, there should be almost no tension/load at the Earth-Cable and Station-Cable connections (except perhaps during operation, and not necessarily even then depending on how you choose to compensate for the load).

      A clarifying question would probably be to ask what's resisting the downward force of *the cable*.

    • The Actual Physics: (Score:5, Informative)

      by BlackGriffen ( 521856 ) on Sunday February 16, 2003 @09:44PM (#5316693)
      The energy of an object in orbit looks like this:

      E = .5m(dr/dt) + .5 L^2/(mr^2) - GmM/r

      (m = mass of object, r = distance between centers of mass, dr/dt = rate of change of distance between centers of mass, L = angular momentum, G = gravitational constant, M = the mass of the Earth) The first two terms are kinetic energy, and the third is potential. It is possible, however, to group the angular momentum term with the actual potential energy, and what you get looks like a centrifugal force.

      You're right to be concerned, though, because angular momentum looks like this:

      L = m*(omega)*r^2

      ( omega = angular frequency) The object is climbing outward with a constant angular frequency (the cable gaurantees that the object will sweep the same angle in the same amount of time), but the distance between the object and the Earth is increasing, thus the angular momentum of the object is increasing. The exact size of the effect depends on the how the length of the cable compares with the radius of the Earth (change in angular momentum: L - Lo = m*(omega)*(C^2 + 2*C*R) where C = cable length and R = radius of earth), but even if the change isn't big, the angular momentum has to come from somewhere. And it comes from the rock and the cabel (effectively dragging it in a bit). It will probably be massive enough that a single load won't bring it crashing down. Plus, anyone returning to Earth is going to have to, in effect, return the angular momentum they took from the elevator as they climb down.

      So, long story short, there are two things that will keep the thing up over the long haul: one, inbound and outbound traffic will tend to balance each other out; two, we can use vastly more efficient ion thrusters to keep it in orbit. Ion thrusters don't work for launching things, because they are incapable of overcoming the force due to gravity directly. What they excell at, is increasing or decreasing angular momentum once the object is in a frictionless environment, because they use small forces for extremely long firing times (chemical rockest last minutes and have millions of pounds of thrust, ion thrusters can go for weeks or months non-stop and push about as hard as a piece of paper on the palm of your hand; the ion thruster still wins out in terms of amount of fuel used to get the same effect, it just takes longer to do it). Granted, we couldn't have everyone rushing a non-returning payload out to the top at once, so it has its drawbacks, but it would still be vastly more efficient than the present system. If it is even feasible, that is.

      BlackGriffen
  • Question (Score:4, Insightful)

    by KeatonMill ( 566621 ) on Sunday February 16, 2003 @07:50PM (#5316246)
    This is probably a stupid question, but why wouldn't inertia rip it apart? The way I see it happening is as follows: The bottom of the elevator is firmly anchored to Earth and the top is floating in space. The bottom is anchored so its movements match Earth's. The top, however, is so high up that it lags behind a bit and bends the whole elevator. Eventually, the material weakens and bends enough that the Earth pulls it down gravitationally and breaks it in two.

    Also, could this possible create drag in the solar wind and slow the Earth's rotation? (most likely another stupid question)

    • Re:Question (Score:5, Informative)

      by ishmaelflood ( 643277 ) on Sunday February 16, 2003 @08:08PM (#5316316)
      It's not a stupid question. Get a ball on a string and whirl it round. The ball doesn't lag does it? The outward pull of the ball keeps the string taut. The exact same effect will be used by the elevator. Locally, in the atmosphere, the cable will be stationary, so it will have to resist wind loads, but they have worked those out. There is also some drag due to space debris and solar wind, but again they have accounted or that.

      Good article, nice website, fantastic project. As Arthur C Clarke said (I think, loosely), we'll be using a space elevator about twenty years after everyone stops laughing at the idea.

    • Re:Question (Score:5, Informative)

      by Thing 1 ( 178996 ) on Sunday February 16, 2003 @08:20PM (#5316355) Journal
      Also, could this possible create drag in the solar wind and slow the Earth's rotation? (most likely another stupid question)

      Not stupid at all, accurate actually. See their FAQ [highliftsystems.com] .

      The second paragraph ends with:

      The extra angular momentum is stolen from the Earth's rotation; we will have to worry about this effect slowing down the Earth and making the day longer if we ever decide to ship Australia into space.

      It's kinda neat that they used Australia as an example (I read their FAQ a few days ago, before this decision about putting it near Australia was published; they didn't change the example for this recent news).




      OT: the fortune at the bottom of the page is very amusing: "Mr. Spock succumbs to a powerful mating urge and nearly kills Captain Kirk." -- TV Guide, describing the Star Trek episode _Amok_Time_

    • Re:Question (Score:5, Informative)

      by jstockdale ( 258118 ) on Sunday February 16, 2003 @08:20PM (#5316357) Homepage Journal
      First of all, theres no way that the structure could be supported solely from the ground, the bottom is anchored, but thats not why its rotates with the earth. Rather, the top is anchored to some heavy object (read asteroid or the like) that is (somehow) placed into a geosync orbit. The structure merely provides a way to efficiently travel from earth to the other object (as you have a solid medium to push against and facilitate the change in grav. potential).

      P.S. Yes, technically the orbit of the top of the elevator/upper anchor is not geosync, but rather slightly above geosync to allow for the center of mass of the contraption to be geosync in its orbit, (and the bottom anchor then serves to maintain the proper orientation).
    • Re:Question (Score:5, Informative)

      by MillionthMonkey ( 240664 ) on Sunday February 16, 2003 @08:42PM (#5316442)
      There's no reason (in theory) why the bottom has to be anchored to the ground (although it probably would have to be to reduce tension on the elevator material). Ideally the elevator could be set up so that the bottom would hang a few feet off the ground in midair.

      There's also no reason why the top would "lag behind a bit". In fact the orbital speed of the counterweight will tend to increase, not decrease, if the orbit decays below geosynchronous orbit. So it would tend to lag forward, not behind. It would definitely need a transport system to carry rocket fuel up to the counterweight for corrective thrust.

      The real reason why one hasn't been built is the extreme material strength required. Nobody has yet developed a material that can hang suspended for a length of 30,000 miles without breaking. This is why most designs count on the bottom of the elevator touching the ground, so that a significant portion of the elevator's weight can be supported by contact with the earth instead of tension in the elevator. Another mitigating factor is the weightlessness of the material at high altitudes- the parts up near the counterweight hardly contribute any tension at all and can be built especially thick. Even with these two caveats, the required tensile strength is so high that people still talk about exotic materials like buckytubes and single-crystal metals whenever the topic of the space elevator comes up. Without some breakthrough in materials engineering, the project is essentially hopeless.

      • Re:Question (Score:5, Funny)

        by Anonymous Coward on Sunday February 16, 2003 @09:06PM (#5316538)
        Ideally the elevator could be set up so that the bottom would hang a few feet off the ground in midair.

        For technical reasons this only works when the bottom of the elevator ribbon is suspended a few feet about a small wicker basket; however, the idea is sound.

        This also alludes to the second problem in keeping the elevator vertical - once the material strength issues are solved, you still need to find someone who can play the flute indefinitely without stopping. The Perth placement is partly designed to take advantage of the circular breathing techniques developed and perfected by the local didgeridoo players.

      • Just the opposite (Score:5, Insightful)

        by roystgnr ( 4015 ) <roy AT stogners DOT org> on Sunday February 16, 2003 @10:17PM (#5316806) Homepage
        This is why most designs count on the bottom of the elevator touching the ground, so that a significant portion of the elevator's weight can be supported by contact with the earth instead of tension in the elevator.

        First of all, the tendency to buckle makes it vastly more difficult to build a long structure under compression than one under tension. Building a structure to support the elevator from below would be just like building any other skyscraper; you wouldn't get the top of the section under compression to be more than a mile off the ground, and after that you'd still have 25,000 miles to go.

        But perhaps just as importantly, the bottom of a geosynchronous elevator design needs to touch the ground because it needs the base to be pulling down on it, not lifting up. If you want to take a 20 ton payload up the elevator without pulling it down, then the elevator is going to need to be under at least 20 tons of tension at the ground when there is no payload on it.
        • But perhaps just as importantly, the bottom of a geosynchronous elevator design needs to touch the ground because it needs the base to be pulling down on it, not lifting up. If you want to take a 20 ton payload up the elevator without pulling it down, then the elevator is going to need to be under at least 20 tons of tension at the ground when there is no payload on it.

          Naah, not necessarily.

          Say (for simplicity of argument) we have a free-floating design, with a basket hanging a few feet off the ground. In equilibrium, the center of mass of the entire elevator (basket, cable, counterweight) is in geosynchronous orbit.

          You put a 20 ton payload into the basket. This shifts the CM downward by an amount. So you pump (weightless) hydrazine up the elevator to corrective rockets sitting on the counterweight, and the rockets push the CM back up into geosynchrous orbit. They do this by pushing the counterweight into a realm above geosync orbit where it experiences a centrifugal force of 20 tons in the upward direction, and this equilibrates with the 20 tons pulling down on the ground. Of course the centrifugal force isn't a "real" force, it's really just an artifact of inertial effects within a rotating coordinate system.

          Once the CM is in stable orbit again it doesn't matter what you do with forces internal to the orbiting assembly, i.e. between the counterweight and the basket. Pulling the basket up to the level of the counterweight won't alter the CM placement. (Although sideways Coriolis forces on the rising 20 tons will start complicating things on the way up.) Still, the amount of rocket fuel spent raising the payload into orbit this way is much less than with a conventional rocket.

          Your design is slightly different in that you have the CM sitting outside geosynchronous orbit in the realm where it experiences the outward centrifugal force all the time. So you've got the other end attached to the ground, pulling up on it. This is conceptually a little bit simpler to grasp, but it puts increased tension in the cable, and after lifting a certain amount of stuff into orbit, the CM of the system will reach geosynchronous orbit anyway- and all the tension at the ground will be gone.

      • But there is hope (Score:5, Informative)

        by hyesse ( 149181 ) on Sunday February 16, 2003 @10:20PM (#5316820)
        The above post makes an excellent point, there is currently no material that can sustain the enormous stress that would be required to construct a space elevator.

        While there is no current material that yields the necessary strength/mass required in order to built a space elevator, realistic possibilities are on the horizon. Quite simply, with the advent of nanotechnology, we are nearing the technological feasibility of creating a material composed of intertwined nanotubes. This is theoretically the strongest material that can ever be created. Carbon-Carbon bonds are extremely strong and would be extremely densely packed in a nanotube pole. It would be an order of magnitude stronger than steel, as well as significantly lighter.

        While nanotubes can already be readily produced (Dr. Smalley of buckyball fame operates a production facility), strong nanotubes rods have yet to be produced. This is due to a variety of technical hurdles that must still be overcome. Perhaps the foremost obstacle is getting the produced nanotubes to lie parallel to each other. The current production method has the nanotubes forming from a catalyst and then becoming intertwined in a jumbled mess. When tension is applies to the mesh, the rope breaks not within the nanotubes (which would require a great deal of energy), but between the nanotubes, unraveling them from each other. Attempts to get the nanotubes to align properly have failed. Nanotubes are not an easy molecule to work with. They have extremely strong cohesion forces and are very difficult to pull apart from one another. The obvious approach of functionalizing each nanotube in order to orient it correctly doesn't work as doing so causes the nanotube to lose much of its mechanical and electrical promising properties.

        In addition, when nanotubes are put under extreme mechanical stress, the bonds within the nanotube shift. For example, I've seen simulations where the bonds separating two polygons disappears, creating what appears to be a bonding who in the nanotube. The hole then resonates through the nanotube causing significant weakening in the structure.

        At a talk I attended, the most promising idea I heard discussed was a steel/nanotube alloy. The nanotubes would run vertically through the steel, reinforcing the structure in the same way steel rods are often used to reinforce concrete. This would alleviate the risk of the nanotubes becoming unraveled intermolecular while at the same time using their large intermolecular strength to reinforce the structure.

        Of course, without any physical models, this is mere speculation. However, it suffices to say that a there are real possibilities of breakthroughs that would allow for the construction of such a space elevator.
    • Re:Question (Score:3, Interesting)

      By my recollection, geosynchronous satellites are at ~22,000 miles / ~35 km up. In this orbit, obviously, centrifugal acceleration exactly counterbalances gravity. (Else the thing would rise or sink to a different orbit). Objects in higher orbits travel more slowly (they are further away, and therefore fight against less gravity). As I understand it, the space elevator will be geosynchronous, with an elevation far beyond the "force-balanced" geosynchronous orbit point 35 K up. Any geosynchronous object more than 35K up (i.e., the top of the elevator) will be travelling far faster than necessary to maintain its orbit; in fact, it will be fighting like hell to escape to a higher orbit (trading its kinetic energy for gravitational potential energy). The problem is similar to that of many carnival rides -- keeping tethered to the center. I don't think current nanotube manufacturing processes are sufficient to handle these forces. I could be wrong -- I haven't found good public descriptions on nanotube manufacturing.
  • Great Glass (Score:5, Funny)

    by prodangle ( 552537 ) <matheson@@@gmail...com> on Sunday February 16, 2003 @07:50PM (#5316249) Homepage Journal
    Willy Wonka would love this!
  • Fortunately (Score:5, Funny)

    by Timesprout ( 579035 ) on Sunday February 16, 2003 @07:55PM (#5316264)
    Perth also has an extremely large sanatorium to cater for the elevator musak induced madness
  • by Speare ( 84249 ) on Sunday February 16, 2003 @07:59PM (#5316282) Homepage Journal

    Arthur C. Clark wrote a novel, Fountains of Paradise, where the whole premise of the story revolved around the creation of the first space elevator. It's worth a read for anyone who wants to understand the basics of the concept.

  • Monorail (Score:5, Funny)

    by Anonymous Coward on Sunday February 16, 2003 @08:08PM (#5316315)
    "But with a start-up cost of $17 billion, the idea needs strong US and Australian government support."

    Lyle Lanley: Well, sir, there's nothing on earth
    Like a genuine,
    Bona fide,
    Electrified,
    Six-car
    Monorail!
    What'd I say?
    Ned Flanders: Monorail!
    Lyle Lanley: What's it called?
    Patty+Selma: Monorail!
    Lyle Lanley: That's right! Monorail!
  • by roman_mir ( 125474 ) on Sunday February 16, 2003 @08:13PM (#5316333) Homepage Journal
    I don't know about a space elevator (it is a cool idea and hopefully it will actually happen) but how in the world are we expected to believe that a 100,000 km long elevator will work if they still can't get the simple 20 store elevators to always run smoothly. I constantly see broken elevators at work and in many buildings, hell it would suck to get stuck in an elevator 80km above ground, I can just see it: a dark room with 6 people and some lagguage. Everything is going ok and all of a sudden, 40hours after lift off - shebang, nothing works! So they reach for the emergency phone: -Hello? Hello? Anybody out there? I don't think we are moving any more! Anybody at all? Anybody!

    Just like the usual, the mechanics are off for today. It would sure suck to hang up there held by a f...ng thread :)
    • I constantly see broken elevators at work and in many buildings, hell it would suck to get stuck in an elevator 80km above ground, I can just see it: a dark room with 6 people and some lagguage. Everything is going ok and all of a sudden, 40hours after lift off - shebang, nothing works!

      Don't worry. They have a backup-plan: stairs. You can leave the luggage- it will be delivered when (if) you reach the top.

  • Ya know ... (Score:5, Funny)

    by B3ryllium ( 571199 ) on Sunday February 16, 2003 @08:15PM (#5316340) Homepage
    I think they will have to choose the music for this elevator VERY carefully. I mean, how long will it take to get up there? You don't want people to go insane and stuff.

    Although, it would make for a REALLY good tv-movie. :)
  • It seems like.. (Score:4, Interesting)

    by Frank of Earth ( 126705 ) <.frank. .at. .fperkins.com.> on Sunday February 16, 2003 @08:18PM (#5316349) Homepage Journal
    .. only under great circumstances do any modern marvels come to full attrition. Unless there is an actual need, be it military or economic, this project will never "take off the ground"

    Basically, it would take some sort of War or space race with China for this to even be the slightest possiblity. Tax payers will not vote for a 17 billion dollar project unless it was under dire circumstances or felt threatened [alla China]

    Think about all the previous advances in the human culture. So many were spawned from war. For instance, I doubt the common 747 jet airliner would be such a popular mode of transportation today if the Nazi's weren't looking for a plane that could run circles around the allied air force.

    This post is going off in a tangent. I guess what I'm trying to say is that with war comes advancement in technology. Without war, technology is backed by monetary gain. What is to gain by building a space elevator? Unless they can mine diamonds or gold from the upper atmosphere...

    • It's my experience that modern marvels come to full attrition in a distressingly short time.

      KFG
    • Re:It seems like.. (Score:3, Insightful)

      by debrain ( 29228 )
      War need not imply innovation. A war with Iraq et al. won't encourage new technology. It may be used to excuse past expenses in otherwise unjustifiable research, though.

      WRT the anecdotal comment regarding mining diamonds: Potential diamond yield is unlikely to encourage anything, since diamond production is artificially stymied by a cartel. I'm pretty sure you didn't mean it seriously, but it does elucidate the enigma of incentive, which is really the core of this converse.

      I think your comments on a China space race, and allusion to Nazi induced innovation, are right on the money. Let us hope that, with respect to the latter, it is not a price we should have to ever again pay for innovation.
  • Assuming and hoping my basic math isn't off here, and the article meant to say 100,000m, not 100,000km. Given that the Earth's diameter is less than 13,000km, that would be one hell of an elevator - imagine an orange with a string the length of your forearm coming off it.

    100,000km would be almost a third of the way to the moon, right?

    Maybe the plan is much more ambitious than I thought...
    • Yeesh. It really IS that big?

      I always thought this thing was going to just tickle the atmosphere. I was off by a factor of 1000.

      Wow.

      When can I get a ride?
      • In about 2100. Although I think that's the estimated start date of the project.

        Just the base tower is going to be 30 miles high, the cable itself is going to be collosal.

        By the time the carriage reaches the end it should be doing about 7 miles per second.
  • by Kris_J ( 10111 ) on Sunday February 16, 2003 @08:22PM (#5316365) Homepage Journal
    Any local Perth residents that want anything to happen with this project should send a message to the Premier's office using this page [wa.gov.au]. Be polite. (I'm fairly sure this isn't redirected to /dev/null.)
  • Australia? (Score:5, Interesting)

    by djupedal ( 584558 ) on Sunday February 16, 2003 @08:25PM (#5316376)
    What happened to Sri Lanka? I thought the goal was to get as close to the equator as practical.
  • Why Bother? (Score:2, Insightful)

    If you ask me, we put altogether too much emphasis on putting stuff in orbit these days. Manned space exploration has been stalled since the end of the Apollo program; putting people into orbit has become the be-all and end-all. Our focus should be beyond orbit; we should head back to the moon, and then on to Mars. Right now, we are doing fine using disposable rockets to put satellites into orbit, and assuming that the investigation into the Columbia disaster comes up with substantive results and recommendations, the shuttle program can continue to put people into orbit (and we end up grounding the shuttles, I don't see why we can't use Soyuz-like capsules to send people to orbit). If we're planning new space technologies (and major space-related capital commitments) I think we must literally aim higher than Earth orbit. While a space elevator would be an incredible technical achievement, it should wait until we have enough in the way of manned orbital stations to justify the cost, or until private companies want to pay for it as a satellite delivery system.

    If we're going to spend that much money on space, we should spend it on space exploration.

    • Yes but any real space exploration should start in space. With a space elevator, it would be feasable to start construction of ships in space, and from there we travel to the Moon, Mars and beyond.
    • Re:Why Bother? (Score:3, Insightful)

      by Dyolf Knip ( 165446 )
      Firstly, manned missions have been stalled because it costs $10,000 to $20,000 to put a single pound in orbit and people require an awful lot of support to go with them. Secondly, LEO is indeed the starting point for getting anywhere else. The Apollo approach of sending up the entire voyage from the ground and back in one module will never work for anything bigger. You have to send up parts and assemble them in space. Thirdly, pure exploration we can mostly do with automated probes. It's nice and informative, but not our goal, which is getting large populations of human beings off this rock. Be it colonizing other planets, space habitats, mining asteroids and comets, or whatever.
    • Re:Why Bother? (Score:3, Insightful)

      by gilroy ( 155262 )
      Blockquoth the poster:

      putting people into orbit has become the be-all and end-all. Our focus should be beyond orbit; we should head back to the moon, and then on to Mars.

      Don't take this as flamebait, but this sort of thinking is exactly why things have stalled: A penchant for the flashy combined with essentially no understanding of what's actually involved in space exploration, nor of what's needed.


      If you want to settle the Moon or explore Mars or any other grandiose thing, you're going to absolutely need cheap Earth-to-orbit capability. Right now it's about $10,000 per pound that we lift -- that means almost nothing can be profitably put into orbit. Bring that down, and the rest follows.


      To stretch a historical analogy, while exploration of North America occured since 1500, massive settlement of it awaited the railroads and cheap transport. (And put down those flamethrowers ... I am not trying to discount the Native American presence in North America. Of course, without railroads, that took literally thousands of years. With railroads, that population was exceeded in about 100 years.)

    • Re:Why Bother? (Score:3, Interesting)

      by cybercuzco ( 100904 )
      Yes, great idea, and why dont we travel the second half of a journey first, because that way we get there faster and dont have to go through the first part. You need to get into LEO if you want to go anywhere in the solar system other than earth.


      it should wait until we have enough in the way of manned orbital stations to justify the cost

      Transportation systems come first, then comes money making. If we wated to have a global system of communications satellites before launching rockets, we wouldnt have any system. In the rainforest, roads come first then the settlers and lumberjacks. If you ever fly across america you can see little strings of towns founded along sometimes now extinct railroad lines. Urban sprawl is a result of increased roadbuilding and major interstates. When the first interstates were built they were mostly empty. Theres a story i heard about some family that was lost on the Washington DC beltway and just made a U-turn in the middle of it because there was no traffic. Try that today. Transportation systems are the ultimate "if you build it, they will come" phenomenon. Private companies wont pay for it, private companies want a 5 year break even with a 30% rate of return. Good luck on even getting the thing built in 5 years, let alone getting it to break even. There are some things only govt can do because buisness is always looking at next quarters bottom line and not the bottom line 10 years from now.

  • by RNLockwood ( 224353 ) on Sunday February 16, 2003 @08:41PM (#5316433) Homepage
    I thought that the anchor needed to be on the equator and Perth is aoubt 36 degrees south. I would imagine that there would be really large lateral forces on the anchor and suspect that the cable would be curved.
  • by gweg ( 646212 )
    OK, so I'm not a physicist or a geographer, but... don't these things had to be positioned at (or near) to the equator (like a geo-synchronous satellite)? Otherwise they would sway and stretch because the orbit would not match the ground.
  • So what's going to happen when the Romulans go flying by and decide to try to tow the earth into the sun?
  • Space elevators are central to Robinson's 'Mars' trilogy as well ("Red Mars," "Green Mars," "Blue Mars"). Highly recommended if you're into Mars. ^_^
  • the heinlen novel "Friday" which describes a system with space elevators that go to the lagrangian points. worth a read any way you cut it though.
  • What I want to know is how they'll get it into space?

    I can imagine a 100,000km elevator coiled up in the australian desert, then a shuttle launched with it tied to the back. The huge coil slowly unwinds, only to be dragged across Australia, levelling perth!

  • Not on the equator? (Score:5, Interesting)

    by Michael Woodhams ( 112247 ) on Sunday February 16, 2003 @10:16PM (#5316798) Journal
    I don't understand how they can base it so far from the equator. If you start the counterweight south of the equator, above Perth, it will be way north of the equator 12 hours later.

    In more detail:
    In a reference frame rotating with the Earth, the counterweight has three forces on it:

    Gravity: G m M_earth / r^2
    towards the center of the earth
    'Centrifugal' force (because we are in a rotating frame): v^2 / r cos l (l = latitude) directed perpendicular to and away from the earth's axis
    Tension on the cable.

    We want these three forces to cancel out, so that the counterweight is stationary (in the rotating frame.) The problem is that the gravity force has a north/south component unless the counterweight is on the equator. The centrifugal force can't have a north/south component, so the balancing force has to come from the cable tension.

    The cable will have be at a small angle to vertical, and the north/south component of the tension is proportional to the sine of this angle, so that component can't be big.

    Aha! I think I have the solution.I was thinking of the counterweight being above the tether point.

    In the 1st approximation, put the counterweight in geostationary orbit (i.e. on the equator). Run the cable to it.

    If the cable had no tension, we would done - but it does. The major component of the tension is towards the earth. We compensate for this by moving the counterweight into a higher orbit. (Decreases gravity, increases centrifugal force, to balance the tension.) There is nothing new here - the Highlift Systems website talks about this.

    If the cable was anchored south of the equator, it will have a slight angle to vertical, which will give a southwards force component. If we now modify the orbit of the counterweight to be slightly south of the equator, there will be a northward component to the gravity vector. We can adjust to balance.

    From the point of view of the tether point, the cable (if it is straight) will be pointing almost towards the geostationary point. From 30 degrees south, that would be a point about 3000 km north and about 35 km up, so it would be about 5 degrees off vertical.

  • Energy generation? (Score:5, Interesting)

    by artemis67 ( 93453 ) on Sunday February 16, 2003 @10:38PM (#5316881)
    The section of their FAQ [highliftsystems.com] that discusses the problem of large electrical currents generated by long space tethers was really interesting...

    Would it be feasible to create a tether to low-earth orbit for the express purpose of generating electricity? I wonder how the cost would compare over the long-term to other low-cost sources like wind and nuclear.
  • by deblau ( 68023 ) <slashdot.25.flickboy@spamgourmet.com> on Monday February 17, 2003 @12:50AM (#5317453) Journal
    Three things. Keep in mind that Perth is situated at roughly 31.95 degrees South.

    One, if the elevator is to remain in a fixed place above the Earth, the radial force (tension) must balance the inertia. For this to happen, a quick calculation shows that at that latitude, the center of mass of the elevator must be 18% higher than the geosync height over the equator. You'll have to put a massive asteroid into orbit at roughly 30k miles up going thousands of miles an hour to anchor this sucker.

    Two, that asteroid will orbit with a 32 degree angle of inclination until it's actually connected to the elevator. I pity the poor fool that has to play catch with that thing in orbit and actually link it to the elevator. If anything goes wrong, the asteroid drops to Earth, bringing devastation on a global scale. All of the previous discussion assumes that the elevator remains perfectly vertical, which brings me to...

    Three, if you anchor a space elevator to the Earth at any latitude but 0 degrees (the equator), you're going to have a lateral inertial component, perpendicular to the radial, that'll bend that rope like a taut bow string. Another calculation shows that the shear force on that rope will be almost 53% of the tension. (This is simple trig.) Carbon nanotubes may have a hella strong tensile strength, but has anyone looked at their shear strength? I wouldn't want the thing to snap like a twig just after they get Mr. Doomsday Rock into position to fuck us worse than the dinosaurs...

  • Unobtainium (Score:3, Informative)

    by Animats ( 122034 ) on Monday February 17, 2003 @03:19AM (#5317969) Homepage
    The big problem is the ribbon material. So far, the longest nanotubes available are a millimeter or so long. Still, this is way ahead of where things were a few years ago.

    When you can buy spools of this stuff, it's time to take this seriously. But not yet.

  • by mamahuhu ( 225334 ) on Monday February 17, 2003 @05:40AM (#5318254) Journal
    I'm appalled at the lack of imagination shown by most of these posts.

    First off if you read the PDF (15M) report [usra.edu] to Nasa [usra.edu] prepared by Bradley C. Edwards to satisfy the requirements of his $500 000 grant you will readily see that this is totally feasible.

    Next check out the website [highliftsystems.com] - where they are calling for people to express interest in working on this project. They expect to be hiring in the next year or so. You'll also see that serious people are taking this seriously. Do you want a job?

    Next understand that $17B is not very much money. Considering that BP just spent [rferl.org] $6.7B on a oil company in Russia and has plans for more purchases.

    I meantion BP because they have a plan to move beyond oil.... BP Solar [bpsolar.com] is BP's attempt to become a broader energy company (check out their new sun logo) instead of an oil company. The High Lift systems news page says: -

    BP Solar - a subsidiary of British Petroleum, currently doing $300M in annual sales. Our discussions have focused on BP's interest in using the SE for deployment of a solar energy satellite. Several items that came up included possible collaborative efforts, the performance of our system and the possibility of BP using our system. They are considering writing a letter of endorsement

    If BP with the cash they have can throw $6.75 B at Russia they could, over 5 years, finance a large share of the Space Elevator. Who needs the Government? In fact Nasa would make sure it costs more to build than it should. Nasa is a bureaucracy, not a business, and is ill-suited to the sort of cost control required of economically viable business decision. Only communists would argue that a Space Elevator should be built and controlled by government.

    What would BP Solar do? Build Power Sats [powersat.com]....

    These are High Lift's vision for the main use for the Space Elevator. Imagine a fleet of these beaming power to anywhere on earth. Every country on the planet could get cheap electricity without the huge national grid infrastructure required now. Without the huge investments in time and resources to build power stations - and without the fossil fuel use.

    Use your imagination.

    These ideas have been the subject of SF for decades - but the Space Elevator is now possible due to those nifty Carbon Nano-tubes.

    When your imagination focussed by the reality of this thing actually being built in the near term (5 years) everything changes - and it'll change for us not our children. It'll change our careers.

    Imagine this - an electric airplane that is powered by a Powersat beaming microwaves to it. No fuel to carry, super efficient travel - and at what speeds?

    These guys are planning for the Space Elevator to be operational SOON - they have realistic timelines.

    What I want to see here is some discussion of the uses that could realistically be made of a space elevator. We're the generation that will built it, use it and be changed by it. I like the parallel to be made with electricity, or flight, or the steam engine - in the early stages everyone probably dismissed it - and the world changed despite them.

    What would you realistically (with a nod towards economic viability) do with the low launch costs they're projecting - $10/LB...

    Ideas anyone?

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