I don't have a problem with sarcasm and critics - I desperately need it to to make it work.
But let me try to adress the feedback we got:
Actually properly fllying in the typical steroid with a large mass and rendevouz it with the tether is quite a complex thing and there have been already papers written on this and lots of compuer simulation done - really scaring, because it is like catching a huge baseball with a thin string - if the ball introduces to much stress because he needs to be accelerated by the hose you get a terrible effect, if it is too fast the stress in the tether to slow it down could blow the whole thing. And our current technology is not that great in flying asteroids BTW.
So the whole counterweight thing is not such a great solution as it actually looks at the first glance (it just makes you scream louder for carbon nanotubes, and hope that they will be also flexible) Remember I looked first into the problems of the existing concepts before creating my own.
Actually the slides on the space hose contain at least some thoughts about the velocity bowing problem:
The good thing for the Space hose is that 100km is only very very much less then 36000km - and because centripedal force F=mv²/r you the difference is even MUCH smaller. Actually you don't have orbital speed either (which would be a nightmare due du the ² and a diameter is 720x smaller (72000km vs. 100km). So you have to instantly drop quite a number of zeros in your worries.
The real speed difference top to bottom is in the slides - it is 26km/h or a moderate 7,27m/sec (which is about 2x the blowing speed - and I already commented multiply that something like 10m/sec is much more likely if you need extra weight for strengthening and want to have optimal blowout speed).
But anyway, this means that it will take approximately 2min to move the top 1km (1% of height). Hence you are right - if erected straight up it will fall - pretty fast.
On the other hand you are absolutely right, if the hose hose has same angular speed there should be no real problem out of the speed difference, and even some bowing. If you erect the hose in a day as suggested (but let's take the 8h that the air would travel trough when you blow into with 3,5m/sec - which is not correct because due to gas expansion by decreasing pressure the air will be much faster). Then you would have 8h to accelerate the top of the hose to 7,2m/sec - Which gives you 7,2/8/3600=0,00025m/s² if we assume continuous acceleration. With the air blown out on the top in 8h (rememmber we talk about a minimum of 618m³/h on the bottom, which is 625x618m³ at the top) you can easily produce this very weak acceleration to give to the entire hose (the 283kg) the proper angular speed. And yes, it will curve during erection, and probably even stay that way - that is the great thing about a hose - it can do this - as long as it is strengthened to hold the remaining pull forces.
But you are right - you could see the entire hose as a 100km long wall effect. If you take a wind tunnerl and hang a diametric wool string into it which is lose enough it will form something very similar to the parabolic velocity curve the gas is showing when flowing laminar. But it will be ONLY pull forces in the entire wool string.
Now let's try to find out how big this pull force could be. I'm a bad guy and hate integrals (to get the exact number). So let's be lazy and put the entire mass of the hose (283kg) at 100km height:
radius=6478000m (6378km Earth radius + 100km hose)
speed=2*6478000/24/3600=471m/sec (the famous 0,4km/s that you can save when starting your rocket east at the equator - reducing orbital speed difference from 7,8km/s to 7,4km/s)
F=283*471²/6478000=9,7N - now I'm really scared :-)
The hose at 250mm diameter and 0,004mm thickness has 250*pi*0,004=3,14mm²
At 20N/mm² tearing strength this means the hose can hold about 63N This is NOT much, but already could hold this centripedal force without the planned Dyneema string strengthening. BTW this is the reason why industrial PE foil is sold in 12/25/50micrometer thickness - because then if plastic bags are made out of the hose your grocery pruchases are save - because 63N is not really what you get when doing family shopping (=6kg). I simply have choosen the 0,4 so that the 100km is a neat roll of foil, and that I can easily add strengthening without blowing the friction lift concept by needing a thunderstorm to hold it upright. A hose up to maybe 1ton, can be held with a moderate airflow in my understanding which would produce pressures which are handable by the suggested materials.
And regaring the wiggeling because of turbulent flow. You are right, but a hose with a reasonable pressure surpluss is also the perfect damping device, especially when it is smooth and long. Because both the hose and the air are not heavy and hydrostatic pressure is balanced from outside I'm not sure if this would be that bad as you suggest. The air petrol station toy is not only wiggeling because of turbulence, it is because of the desing to reduce the diameter so that airflow increases, presure goes down until the outside pressure is bigger and the hose bows sidewards, then the pressure increase due to the closed hose puts it upright again. So it is designed as a kind of penumatic pendulum.
Try the same with a fixed diameter hose and a diffusor on top for generating pull forces. And even a fully turbulent airflow in a hose has a thin laminar piece at the walls of the hose (because of the lower frequency there). Hence the turbulences are not really scaring me - it is the increasing flow speed (if it is not compensated by diameter adaption, diffusors,..) which theoretically goes beyond the speed of sound. But nobody commented on this so far.
gutemine
