Space Elevator 24


Space Elevator 24 : Construction: Space elevator construction. The construction of a space elevator would need reduction of some technical risk. Some advances in engineering, manufacturing and physical technology are required. Once a first space elevator is built, the second one and all others would have the use of the previous ones to assist in construction, making their costs considerably lower. Such follow-on space elevators would also benefit from the great reduction in technical risk achieved by the construction of the first space elevator. Construction is conceived as the deployment of a long cable from a large spool. The spool is initially parked in a geostationary orbit above the planned anchor point. When a long cable is dropped "down" (toward Earth), it must be balanced by balancing mass being dropped "up" (away from Earth) for the whole system to remain on the geosynchronous orbit. Earlier designs imagined the balancing mass to be another cable (with counterweight) extending upward, with the main spool remaining at the original geosynchronous orbit level. Most current designs elevate the spool itself as the main cable is paid out, a simpler process. When the lower end of the cable is so long as to reach the Earth (at the equator), it can be anchored. Once anchored, the center of mass is elevated upward more (by adding mass at the upper end or by paying out more cable). This adds more tension to the whole cable, which can then be used as an elevator cable. One proposal suggests using conventional rockets to place a "minimum size" initial 19,800 kg seed cable, adequate to support the first 619 kg climber. The first 207 climbers carry up more cable, widening the initial ribbon to about 160 mm wide at its widest point. The result is a 750,000 kg cable with a lift capacity of 20 tons per climber. Another proposal results in a system weighing about 1500 tons (including counterweight), with the ribbon about 1 meter wide at its widest point, and can carry up to one 15 ton payload per day. Another proposal results in a system with a lift capacity of 1 ton, at a constant cable stress of 50 GPa, and calculates a taper ratio of 4. 28, a 97,700 kg cable, and a 52,700 kg counterweight at the far end. Another proposal estimates that a "20-ton" elevator -- an elevator that could support a single 20 ton climber -- would require a tether mass of 4000 to 6000 tons
No records Found
afaatim.com copyright © April 2016 Dr.K.R.Kamaal. All rights reserved