Difference between revisions of "Colonising Space/Access to space"

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*{{wp|Scramjet|Scramjet}} / rocket hybrid, such as the {{wp|Single-stage-to-orbit|single stage to orbit}} (SSTO) {{wp|Skylon|''Skylon''}} launch vehicle
 
*{{wp|Scramjet|Scramjet}} / rocket hybrid, such as the {{wp|Single-stage-to-orbit|single stage to orbit}} (SSTO) {{wp|Skylon|''Skylon''}} launch vehicle
 
*Balloon platform.
 
*Balloon platform.
*Space guns like [http://en.wikipedia.org/wiki/Project_HARP HARP]
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*Space guns like {{wp|Project_HARP|HARP}}. Anything propelled upwards at a speed over 11.2 kilometers per second will escape Earth's gravitational pull and get into space. One of the most straightforward ways to reach this fantastic speed is by firing payloads out of the barrel of an enormous gun. This would provide a very cheap and practical way of putting materials in space, but the large ''g'' forces involved would make it unsuitable for humans or sensitive equipment.
*Other theoretical methods
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*Linear motor assisted launch from high altitude terrain
**Linear motor assisted launch from high altitude terrain
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*{{wp|Space_elevator|Space elevator}}. Picture a satellite tethered to the Earth {{em}} a large weight in geosynchronous orbit is attached by a strong, long, light cable to an anchor-point on the planet's surface. Robots could climb this cable, carrying payloads into space. This is expected to reduce the cost of transporting a pound of material into space to $100 <sup>[http://www.canada.com/saskatoonstarphoenix/news/story.html?id=3dd5119f-1951-46a5-b4af-bd9eb49228a9]</sup>, which would completely open up space to all kinds of new ventures. However, there are still many challenges to be overcome before a space elevator is viable: the robots that ascend the cable need a reliable power source, there are dangers of the cable being snapped by lightning strikes, asteroids or orbiting debris and there is doubt as to whether [[Advanced materials|carbon nanotube]] cables can be made strong enough to withstand the tension generated by such an enormous structure.
**{{wp|Space_elevator|Space elevator}}. Picture a satellite tethered to the Earth {{em}} a large weight in geosynchronous orbit is attached by a strong, long, light cable (probably made using [[carbon nanotubes]], though there is controversy over whether these can be made strong enough) to an anchor-point on the planet's surface. Robots could climb this cable, carrying payloads into space. This is expected to reduce the cost of transporting a pound of material into space to $100 <sup>[http://www.canada.com/saskatoonstarphoenix/news/story.html?id=3dd5119f-1951-46a5-b4af-bd9eb49228a9]</sup>, which would completely open up space to all kinds of new ventures. However, there are still many challenges to be overcome before a space elevator is viable: the robots that ascend the cable need a reliable power source, there are dangers of the cable being snapped by lightning strikes, asteroids or orbiting debris and there is doubt as to whether cables can be made strong enough to withstand the tension generated by such an enormous structure.
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*A {{wp|Launch_loop|launch loop}} (illustrated [http://www.youtube.com/watch?v=hCwVjUZV92Q here]) is perhaps more feasible than a space elevator as it requires no new materials. It is essentially a conveyor belt to space. It consists of a loop of iron cable anchored on the surface of the Earth at one end, and at a height of 125km above the Earth at the other end. The loop passes through electromagnetic bearings at each end. These bearings spin the cable at high speeds, which creates a centrifugal force that lifts the cable up into an enormous loop, the top half of which is in space. Payloads can use magnets to attach themselves to the cable and ride it into space.
**A {{wp|Launch_loop|launch loop}} (illustrated [http://www.youtube.com/watch?v=hCwVjUZV92Q here]) is perhaps more feasible than a space elevator. It is essentially a conveyor belt to space. It consists of a loop of iron cable anchored on the surface of the Earth at one end, and at a height of 125km above the Earth at the other end. The loop passes through electromagnetic bearings at each end. These bearings spin the cable at high speeds, which creates a centrifugal force that lifts the cable up into an enormous loop, the top half of which is in space. Payloads can use magnets to attach themselves to the cable and ride it into space.
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Revision as of 19:33, 19 July 2010

We now have access to space using rockets. However this is an expensive way to get into space (over $5000 per pound of material launched[1]) and the failure rate is high. This severely limits what we can do in space: it is the main obstacle to space solar power, space tourism and large-scale space habitats. So far, we have only dipped our toes into space; if we want to really dive in, we need an efficient, reliable way of getting large amounts of material beyond the Earth's gravitational pull. While incremental improvements in rocket technology may suffice, several very different ways of getting off the planet have been proposed.

  • Multi-stage rocket
  • Aircraft piggy-back
  • Scramjet 11px-Wikipedia_logo.jpg / rocket hybrid, such as the single stage to orbit 11px-Wikipedia_logo.jpg (SSTO) Skylon 11px-Wikipedia_logo.jpg launch vehicle
  • Balloon platform.
  • Space guns like HARP 11px-Wikipedia_logo.jpg. Anything propelled upwards at a speed over 11.2 kilometers per second will escape Earth's gravitational pull and get into space. One of the most straightforward ways to reach this fantastic speed is by firing payloads out of the barrel of an enormous gun. This would provide a very cheap and practical way of putting materials in space, but the large g forces involved would make it unsuitable for humans or sensitive equipment.
  • Linear motor assisted launch from high altitude terrain
  • Space elevator 11px-Wikipedia_logo.jpg. Picture a satellite tethered to the Earth — a large weight in geosynchronous orbit is attached by a strong, long, light cable to an anchor-point on the planet's surface. Robots could climb this cable, carrying payloads into space. This is expected to reduce the cost of transporting a pound of material into space to $100 [2], which would completely open up space to all kinds of new ventures. However, there are still many challenges to be overcome before a space elevator is viable: the robots that ascend the cable need a reliable power source, there are dangers of the cable being snapped by lightning strikes, asteroids or orbiting debris and there is doubt as to whether carbon nanotube cables can be made strong enough to withstand the tension generated by such an enormous structure.
  • A launch loop 11px-Wikipedia_logo.jpg (illustrated here) is perhaps more feasible than a space elevator as it requires no new materials. It is essentially a conveyor belt to space. It consists of a loop of iron cable anchored on the surface of the Earth at one end, and at a height of 125km above the Earth at the other end. The loop passes through electromagnetic bearings at each end. These bearings spin the cable at high speeds, which creates a centrifugal force that lifts the cable up into an enormous loop, the top half of which is in space. Payloads can use magnets to attach themselves to the cable and ride it into space.