 Artist's conception of satellite with a tether Tether propulsion uses long, strong strings (known as tethers) to change the orbits of spacecraft. It has the potential to make space travel significantly cheaper. Artists conception of satellite with tether. ...
A tether is a cord that anchors something to something else, such as a pole. ...
In physics, an orbit is the path that an object makes, around another object, whilst under the influence of a source of centripetal force, such as gravity. ...
A spacecraft is a vessel, craft or device designed to operate beyond the surface of the Earth in outer space. ...
Some current tether designs use crystalline plastics such as Dyneema. A possible future material would be carbon nanotubes, which have a theoretical tensile strength of at least 60 GPa. Dyneema or Spectra is a synthetic fiber based on ultra high molecular weight polyethylene which is 15 times stronger than steel and up to 40% stronger than Kevlar. ...
3D model of three types of single-walled carbon nanotubes. ...
1 At earth mean sea level. ...
Usage
Electrodynamic tethers -
An electrodynamic tether is a conductive tether which generates current and, among other possibilities, acts against a planetary magnetic field. It can be used either to accelerate or brake an orbiting spacecraft. When the tether cuts the planet's magnetic field, it generates a current, and thereby reduces the energy of the spacecraft. When direct current is pumped through the tether, it exerts a force against the magnetic field, and the tether accelerates the spacecraft. Other applications of electrodynamic tethers are for power generation. Electrodynamic tethers are long conducting wires (such as the one deployed from the tether satellite) which can operate on the well known electromagnetic priciples as a generator (via converting its velocity to electric energy) or engine (ultilizing electric energy for velocity). ...
To meet Wikipedias quality standards, this article may require cleanup. ...
In physics, an orbit is the path that an object makes, around another object, whilst under the influence of a source of centripetal force, such as gravity. ...
A magnetosphere is the region around an astronomical object in which phenomena are dominated or organized by its magnetic field. ...
Direct current (DC or continuous current) is the continuous flow of electricity through a conductor such as a wire from high to low potential. ...
Tidal stabilization -
Main article: Gravity-gradient stabilization Gravity-gradient stabilization, also called "gravity stabilization" and "tidal stabilization", is cheap and reliable. It uses no electronics, rockets or fuel. Gravity-gradient stabilization is a method of stabilising artificial satellites in orbit and maintaining optimum attitude for solar power, communications and sensors. ...
An attitude control tether has a small mass on one end, and a satellite on the other. Tidal forces stretch the tether between the two masses. There are two ways of explaining tidal forces: In one, the upper part of an object goes faster than its natural orbital speed, so centrifugal force stretches the object upwards. The lower part moves slower than the orbital speed, so it pulls down. Another way to explain tidal force is that the top of a tall object weighs less than the bottom, so they are pulled by different amounts. The "extra" pull on the "bottom" of the object stretches it out. On Earth, these are small effects, but in space, nothing opposes them. // In the context of spacecraft, attitude control is control of the angular position and rotation of the spacecraft, either relative to the object that it is orbiting, or relative to the celestial sphere. ...
MILSTAR:A communication satellite A satellite is any object that orbits another object (which is known as its primary). ...
Comet Shoemaker-Levy 9 after breaking up under the influence of Jupiters tidal forces. ...
Centrifugal force (from Latin centrum center and fugere to flee) is a term which may refer to two different forces which are related to rotation. ...
The resulting tidal forces stabilize the satellite so that its long dimension points towards the planet it is orbiting. Simple satellites have often been stabilized this way, with tethers or mass distribution. A small bottle of fluid must be mounted in the spacecraft to damp pendulum vibrations with the friction of the fluid motion.
Rotovators The word rotovator is a portmanteau derived from the words rotor and elevator. A rotovator is a high speed rotating tether (sometimes called momentum exchange tethers), rotated so that the tips have a significant speed (~1-3 km per second). This article or section does not cite its references or sources. ...
R0t0r is from efnet ...
A set of elevators or lifts, in the lower level of a London Underground station. ...
A spacecraft could rendezvous with one end of the tether, latch to it, and be accelerated by the tether's rotation. The tether and spacecraft would then separate at a later point when the spacecraft's velocity has been changed by the rotovator.
This is not free. The tether's momentum and angular momentum is changed, and this costs energy that must be recouped. The idea is that the recharge could be done with some form of energy (for instance solar panels generating current for electromagnetic propulsion) that is far, far cheaper than multi-stage-rocket fuel. In classical mechanics, momentum (pl. ...
Gyroscope. ...
Solar Panel made by BP Solar The solar panels (photovoltaic arrays) on this small yacht at sea can charge the 12 V batteries at up to 9 Amps in full, direct sunlight. ...
Electric current is by definition the flow of electric charge. ...
Electromagnetic Propulsion using the concepts and applications of electromagnets. ...
Rocket fuel is a propellant that reacts with an oxidizing agent to produce thrust in a rocket. ...
Rotovators can also be used to slow down incoming spacecraft, thus increasing the rotovator's momentum. If the average momentum gained from inward traffic equals that imparted to outward traffic, there is no net energy cost, and thus nothing to recoup.
An example of use would be a rotovator in a circular orbit, with the tip velocity zero relative to (or at) the ground that grabs an object from high altitude. This kind of earth-to-orbit rotovator (skyhook) cannot be built from currently available materials since the centripetal acceleration would be many times greater than their stress tolerances . A "watered down" rotovator with two-thirds the rotational speed, however, would halve centripetal acceleration stresses. In astrodynamics or celestial mechanics a circular orbit is an elliptic orbit with the eccentricity equal to 0. ...
The centripetal force is the external force required to make the body move in a circular path with uniform speed and directed towards the center. ...
Figure 1 Stress tensor A mature tree trunk may support a greater force than a fine steel wire but intuitively we feel that steel is stronger than wood. ...
On airless bodies with reasonably low orbital speed (such as the Moon), a rotovator in low orbit can actually touch the ground, thereby providing cheap surface transport as well as launching materials into cislunar space. Although it might be thought that this requires constant energy input, it can in fact be shown to be energetically favourable to lift cargo off the surface of the Moon and drop it into a lower Earth orbit, since the moon's surface is in a comparatively higher potential energy state. By the "launching" of materials in loops, the system can keep going indefinitely. Adjective lunar Bulk silicate composition (estimated wt%) SiO2 44. ...
Cislunar space (alternatively, cis-lunar space) is the volume within the Moons orbit, or a sphere formed by rotating that orbit. ...
Rotovators can thus be charged by momentum exchange. Momentum charging uses the rotovator to move mass from a place that's "higher" in a gravity field to a place that is "lower". The energy from the falling weight speeds up the rotation of the rotovator. For example, it is possible to use a system of two or three rotovators to implement trade between the Moon and Earth. The rotovators are charged by lunar mass (dirt, if exports are not available) dumped on or near the Earth, and can use the momentum so gained to boost Earth goods to the Moon. In classical mechanics, momentum (pl. ...
The gravity field is the field of force, caused by the gravitation of the Earth, and influenced by the Earth rotation, the atmosphere and by geological bodies. ...
Adjective lunar Bulk silicate composition (estimated wt%) SiO2 44. ...
Earth (IPA: , often referred to as the Earth, Terra, the World or Planet Earth) is the third planet in the solar system in terms of distance from the Sun, and the fifth largest. ...
Systems of rotovators could theoretically open up inexpensive transportation throughout the solar system as well, as long as the net mass flow is towards a massive body, such as the Sun, or the Earth. Major features of the Solar System (not to scale): The Sun, the eight planets, the asteroid belt containing the dwarf planet Ceres, outermost there is the dwarf planet Pluto (the dwarf planet Eris not shown), and a comet. ...
For other uses, see Sun (disambiguation). ...
Earth (IPA: , often referred to as the Earth, Terra, the World or Planet Earth) is the third planet in the solar system in terms of distance from the Sun, and the fifth largest. ...
In a strong planetary magnetic field such as around the Earth or Saturn, a conducting rotovator can be configured as an electrodynamic tether. This can either be used as a dynamo, which slows the tether and changes the angular momentum whilst generating electrical power, or alternatively, its orbital speed and/or angular momentum can be increased electrically from solar or nuclear power by running current through a wire that goes the length of the tether. Such a tether pushes against the angular momentum of the planet. Adjective Saturnian Atmospheric characteristics Atmospheric pressure 140 kPa Hydrogen >93% Helium >5% Methane 0. ...
Electrodynamic tethers are long conducting wires (such as the one deployed from the tether satellite) which can operate on the well known electromagnetic priciples as a generator (via converting its velocity to electric energy) or engine (ultilizing electric energy for velocity). ...
Dynamo, or Dinamo, may refer to: Dynamo, an electrical generator Dynamo (sports society) of the Soviet Union Operation Dynamo, the 1940 mass evacuation at Dunkirk Dynamo, the rock band based in Belfast Dynamo theory, a theory relating to magnetic fields of celestial bodies Dynamo Open Air, annual heavy metal music...
(One complication to this is that as the tether rotates, the direction of current must reverse.)
A method that may allow for the use of weaker materials is to put the rotovator in an elliptical orbit. It would pick up a load at periapsis (closest approach), then vary the tether length or attachment point to throw the load (from the top of the tether) at a later time into a higher orbit. This splits the speed-exchange into two parts, each contributing half of the final velocity. This would reduce the necessary size, strength, and weight of the tether dramatically. One might call it a "revovator" because it exchanges momentum in both revolution and rotation. Recharging such a rotovator would be more complex, however. This article is about several astronomical terms (apogee & perigee, aphelion & perihelion, generic equivalents based on apsis, and related but rarer terms. ...
Another trick to achieve lower stresses is that rather than picking up a cargo from the ground at zero velocity, a rotovator could pick up a moving vehicle and sling it into orbit. For example, a rotovator could pick up a Mach-12 aircraft from the upper atmosphere of the Earth and move it into orbit without using rockets. It could likewise catch such an aircraft and lower it into atmospheric flight. But it is easy to get a rocket to that kind of speed, so "Single Stage To Tether" has also been proposed. Either air breathing or rocket to tether could save a great deal of fuel per flight, and would permit for both a simpler vehicle and more cargo. An F/A-18 Hornet approaching the sound barrier. ...
An important practical modification of a rotovator would be to add several latch points to achieve different momentum transfers. Another useful concept would be to add a linear motor to the rotovator, to accelerate spacecraft or materials to higher speeds than the tip speed of the tether.
Skyhooks -
A tidal stabilized tether is called a "skyhook" since it appears to be "hooked onto the sky". This term was introduced by the Italian scientist Giuseppe Colombo. For other uses, see Skyhook (disambiguation). ...
For other uses, see Skyhook (disambiguation). ...
Giuseppe Colombo (1920-1984), better known by his nickname, Bepi Colombo, was a scientist, mathematician and engineer at the University of Padua, Italy. ...
They are also called "hypersonic tethers" because the tip nearest the earth travels about Mach-12 in typical designs. Longer tethers would travel more slowly. At the limit of zero ground speed, it would be re-classified as a beanstalk. An F/A-18 Hornet approaching the sound barrier. ...
A space elevator would consist of a cable attached to the surface and reaching outwards into space. ...
An aircraft or sub-orbital vehicle transports cargo to one end of the skyhook.
Skyhook designs typically require climbers to transport the cargo to the other end (like a beanstalk).
Robert Raymond Boyd and Dimitri David Thomas (with Lockheed Martin Corporation) patented the Skyhook idea in 2000 in a patent titled "Space elevator"[1]. This article is about the year 2000. ...
Space elevator (beanstalk) -
A beanstalk (a type of space elevator) is a rotovator powered by the spin of a planet. For example, on Earth, a beanstalk would go from the equator to geosynchronous orbit. A space elevator would consist of a cable anchored to the Earths surface, reaching into space. ...
A space elevator would consist of a cable anchored to the Earths surface, reaching into space. ...
A beanstalk does not need to be charged as a rotovator does, because it gets the required energy directly from its planet's angular momentum. The disadvantage is that it is much longer, and for many planets a beanstalk cannot be constructed from known materials. A beanstalk on Earth would require material strengths outside current technological limits (2006). Martian and Lunar beanstalks could be built with modern-day materials however.[citation needed] Gyroscope. ...
2006 (MMVI) was a common year starting on Sunday of the Gregorian calendar. ...
Beanstalks also have much larger amounts of potential energy than a rotavator, and if heavy parts should fail they might cause multiple impact events as objects hit the earth at near orbital speeds. Most anticipated cable designs would burn up before hitting the ground. Artists impression of a major impact event. ...
Propulsion challenges and other problems Simple tethers are quickly cut by micrometeoroids. The lifetime of a simple, one-strand tether in space is on the order of five hours for a length of ten km. Several systems have been proposed to improve this. The US Naval Research Laboratory has successfully flown a long term tether that used very fluffy yarn. This is reported to remain uncut several years after deployment. Another proposal is to use a tape or cloth. Dr. Robert Hoyt patented an engineered circular net, such that a cut strand's strains would be redistributed automatically around the severed strand. This is called a Hoytether. Hoytethers have theoretical lifetimes of tens of years. In low Earth orbit, a tether could be wiggled to dodge known pieces of space junk. Look up meteoroid in Wiktionary, the free dictionary. ...
The US Naval Research Laboratory (NRL) is the corporate research laboratory for the United States Navy and the United States Marine Corps and conducts a broad program of scientific research and advanced development. ...
The Hoytether is a trademarked name from the Tethers Unlimited Incorporated [1] for a novel topology for a space elevator cable, consisting of a lattice of strands, arranged in a circular cross-section, and having redundancy to handle potential damage from space debris or micro meteroids. ...
Beanstalks and rotovators are currently limited by the strengths of available materials. Although ultra-high strength plastic fibers (Kevlar and Spectra) permit rotovators to pluck masses from the surface of the Moon and Mars, a rotovator from these materials cannot lift from the surface of the Earth. In theory, high flying, supersonic (or hypersonic) aircraft could deliver a payload to a rotovator that dipped into Earth's upper atmosphere briefly at predictable locations throughout the tropic (and temperate) zone of Earth. Chemical structure of Kevlar. ...
Dyneema or Spectra is a synthetic fiber based on ultra high molecular weight polyethylene which is 15 times stronger than steel and up to 40% stronger than Kevlar. ...
Mars is the fourth planet from the Sun in the solar system, named after the Roman god of war (the counterpart of the Greek Ares), on account of its blood red color as viewed in the night sky. ...
It has been suggested that hypersonic be merged into this article or section. ...
Boeing X-43 at Mach 7 In aerodynamics, hypersonic speeds are speeds that are highly supersonic. ...
Mechanical tether-handling equipment is often surprisingly heavy, with complex controls to damp vibrations. The one ton climber proposed by Dr. Walter Edwards may detect and suppress most vibrations by changing speed and direction. The climber can also repair or augment a tether by spinning more strands.
Cargo capture for rotovators is nontrivial, and failure to capture is generally catastrophic. Several systems have been proposed, such as shooting nets at the cargo, but all add weight, complexity, and another failure mode. Currently, the strongest materials in tension are plastics that require a coating for protection from UV radiation and (depending on the orbit) erosion by atomic oxygen. Disposal of waste heat is difficult in a vacuum, so over-heating may cause tether failures or damage.
In fiction The mechanics of tether propulsion are critical in resolving the climax of the book The Descent of Anansi by Steven Barnes and Larry Niven. The Descent of Anansi is a novel by Steven Barnes and Larry Niven. ...
Steven Barnes photo by Beth Gwinn Steven Barnes (born March 1, 1952 in Los Angeles, CA) is a self-titled writer, lecturer, creative consultant, and human performance technician. ...
Laurence van Cott Niven (born April 30, 1938) is a US science fiction author. ...
See also A remote camera captures a close-up view of a Space Shuttle Main Engine during a test firing at the John C. Stennis Space Center in Hancock County, Mississippi Spacecraft propulsion is used to change the velocity of spacecraft and artificial satellites, or in short, to provide delta-v. ...
A space elevator would consist of a cable anchored to the Earths surface, reaching into space. ...
References
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