RU2679498C1 - Method for removing space debris from near-earth environment - Google Patents

Abstract

FIELD: cosmonautics ecology.SUBSTANCE: invention relates to methods for cleaning near-Earth environment from space debris (SD). In the cleaned region of space, a spacecraft is launched with self-expanding autonomous mobile networks equipped with controlled maneuverable engines and means of (electro)magnetic retention of SD. At the required moment, the networks open up, and the sensors installed on them, in the case of the capture of SD fragments, transmit information about these fragments to the control panel. Latter generates a command to close the network or another method (for example, electromagnetic) fixing the fragments of the SD and the inclusion of maneuverable engines to perform a debris de-orbiting maneuver.EFFECT: technical result consists in expanding the operational capabilities and the range of removed SD fragments.7 cl

Description

The invention relates to the field of space technology, and in particular to methods for cleaning near-Earth space from space debris.

Space debris is a very big problem for modern astronautics and humanity as a whole. Its volumes are growing at a tremendous pace and it poses a significant threat to the development and use of near-Earth outer space. So, according to NASA estimates, more than 4 thousand active and spent satellites, 13056 stages of launch vehicles, booster blocks and Other space technology and its fragments, 21 thousand objects larger than 10 cm have already accumulated over the Earth. Another 500 thousand particles ranging in size from 1 to 10 cm. And the number of particles less than 1 cm exceeds 100 million. Among space debris, you can find anything - satellites, work tools and even gloves. According to rough estimates, its total mass reaches 7 thousand tons.

If these objects were in low orbits (up to 400 km), in a few years they would burn out in the atmosphere. However, most of them are located much higher, where they will remain for thousands and even millions of years. Sometimes this is what was intended - for example, for resource-consuming military satellites, on which about one and a half tons of radioactive fuel (uranium-235 and plutonium-238) remain. They are deliberately taken out for burial to an altitude of 800-1100 km, where they must remain until their radioactivity decreases - that is, hundreds of thousands of years.

However, in general, such garbage is a threat to space programs of all countries. Its abundance can provoke Kessler's syndrome: putting new objects into orbit will become too risky due to the high probability of a collision. Humanity will block access to space for itself and be isolated.

Now the space debris problem is being dealt with by the Committee on the Peaceful Uses of Outer Space at the UN, as well as the Space Debris Coordination Committee, formed by several national space agencies. In Russia, Roscosmos is engaged in it within the framework of the federal space program Sustainability.

But despite the fact that this problem is known and seriously dealt with, at present there are no effective means for its practical and realistic solution.

At different times, the following solutions were proposed:

- send a satellite into space to catch debris using a harpoon and a network - but what trap will keep an object flying at a speed of 10 km / s?

- use large and thin balloons to wrap objects around, increase their aerodynamic drag hundreds of times and cause them to fall into the Earth’s atmosphere;

- use robots that move satellites back into the atmosphere - but the cost of each mission will be about $ 200 million;

- to release into orbit a dense cloud of tungsten dust - it will settle on the surface of the wreckage, increase its weight and make it leave the orbit. The problem is that along with the debris, the active satellites will also descend from orbit;

- use ground-based lasers to create plasma vortices on space debris; its movement will slow down, and the debris will re-enter the atmosphere. Implementation, again, is hindered by the cost - up to a million dollars per object.

There were also practical attempts, so in January 2017, an experiment by Japanese scientists on garbage collection (Kounotori Integrated Tether Experiment) failed. The unmanned ship was supposed to release a 700-meter electrodynamic leash to capture the wreckage - but it broke.

Thus, it can be seen that the main problem in solving this issue is the high cost, low reliability, low selectivity, as well as the problem of trapping particles, the flight direction of which is difficult to predict, and the speed is extremely high (10 or more times higher than the speed of the bullet) .

It is known (RU, patent 133096, publ. 10.10.2013) a device for capturing space objects containing a spacecraft containing an onboard control complex, the first output of which is connected to a control input of the electric drive, mechanically connected to the input of rotation of the drum, the control input of which is connected to the output of the source electricity, and a cable system made in the form of a cable cable, mechanically connected to the drum shaft, the second output of the onboard control complex is connected to the control input of the electric power source, the branching input of the cable cable is connected to the control input of the drum, in addition, an adhesive pad is mounted on the free end of the cable cable, the control input of which is connected to the control output of the cable cable.

A disadvantage of the known device should be recognized as its complexity, as well as the possibility of removing only one object from orbit.

A known method of cleaning space from space debris (RU, patent 2478062, publ. 03/27/2013) is that they provide braking of objects of space debris in order to transfer them to a lower orbit, followed by the burning of objects in the Earth’s atmosphere. On the way of following objects of space debris by spraying, an obstacle is created in the form of a cloud of spatially distributed particles. As the particle material, nitrogen oxidation products are used, preferably nitrogen oxides I, III, IV, V — N ₂ O, N ₂ O ₃ , NO ₂ , N ₂ O ₄ , N ₂ O ₅ , the state of matter of the particles is a solid. Particles have a kinetic shock effect on objects of space debris. The particle size of the material to influence the objects of space Debris is selected depending on the size of the objects.

The disadvantages of this method is the rather low efficiency due to the relatively large sparseness of the cloud, while the shock-kinetic effect on space debris objects can simultaneously lead to defragmentation of individual objects of space debris, which will lead to an increase in the quantitative composition of space debris. It should also be noted the need for periodic additional formation of an obstacle in the form of a cloud of spatially distributed particles, which will disperse after the passage of particles of space debris.

Known (RU, patent 2046081, publ. 20.10.1995) space net containing a spacecraft and a screen associated with it, interacting with the environment, and the screen is made in the form of two surfaces of flexible film placed on opposite sides of the spacecraft and connected with it by means of cables of adjustable length, the cables being oriented in space along the local vertical, a garbage collection container oriented along it is fixed at the free end of each cable, the inner end of which is made in the form of a funnel, connected with the adjacent edge of the film, and its end with respect to the spacecraft, the end face is equipped with a hatch.

Space net works as follows. The space net is delivered to a given area of outer space and deployed so that the cables are oriented along the local vertical. When space debris interacts with the film material, the relative velocity of the particles is quenched, after which these particles under the action of centrifugal forces enter the containers for garbage collection.

A disadvantage of the known device should be recognized as a narrow scope - only the removal of small space debris - particles.

The known solution is made as the closest analogue of the developed method.

The technical problem solved by the implementation of the developed method is to enable the removal of space debris from near-Earth space.

The technical result achieved by the implementation of the developed method consists in simplifying the method for removing space debris from near-Earth space while expanding the range of deleted fragments of space debris.

To achieve the specified technical result, it is proposed to use the developed method for removing space debris from near-Earth space. According to the developed method for removing space debris from near-Earth space by collecting and removing it from near-Earth orbit into a cleaned area of near-Earth space, a spacecraft is launched that is capable of releasing capsules with self-expanding autonomous mobile networks equipped with controlled maneuverable engines. After the capsules reach the specified speed of the network, the sensors are opened, and the hit sensors installed on the networks transmit information about the object detained by the network to an existing control panel that generates a command to close the network or some other way of fixing captured objects and turning on maneuvering engines to perform maneuver for cleaning garbage from orbit .

The specified control panel can be located on the network itself, the spacecraft, in the flight control center, and on the capsule.

In some embodiments of the method, the filled networks using maneuverable engines are directed toward the earth, followed by flooding or flooding of the contents or burning it in the atmosphere.

In other embodiments of the method, the filled networks using maneuverable engines are directed away from the earth with the subsequent output to a higher orbit or to a given point.

On the networks, optionally Additionally, magnetic and electromagnetic space debris containment facilities can be placed.

Capsules (network carriers) may additionally contain means for detecting space debris.

In some embodiments of the developed method, the filled networks using maneuverable engines are directed towards the ground, followed by a soft landing made using the existing soft landing system, in particular, parachute or splashdown.

In some embodiments of the developed method, the filled networks using maneuverable engines initially move in the direction of the earth, and then release the catch, which will burn in the atmosphere, and then re-enter the garbage collection area.

In some embodiments of the developed method, the released capsule is located in a given region of near-Earth space with a closed network in anticipation of a command to begin work on the capture of garbage coming from both its own sensors and external control devices.

According to the developed method, it is proposed to launch an apparatus in the desired area of near-Earth space, which, according to a given program, would produce special capsules with self-opening autonomous mobile networks, and having various characteristics, such as its own size (from tiny, with a palm or smaller, to huge ), cell size, material of manufacture, size of engines, energy supply, availability of soft landing systems, etc., depending on the problem being solved.

After receiving a given speed, these capsules open networks that for some time collected what gets into Them without collapsing, thanks to the existing shunting engines, while avoiding fatal damage due to the mesh structure and equal speed, also receiving information from hit sensors and sending it to the control point, and then, if necessary, capture what was collected (by mechanically shutting it, including electromagnets, or in another way), by command or by a pre-established program, they would give an impulse to atelier in the right direction and either burned in the atmosphere / flooded in the ocean, or if the cargo was needed - it would be lowered by parachute into the given area. It is also possible that the trapped garbage is transferred to a higher orbit or to a predetermined point, for example, in the future there could be an automatic garbage recycling station to save on the delivery of materials, for example, for an international space base under construction, an interplanetary or interplanetary ship.

To reduce the cost, such networks could be reusable, i.e. if they caught and secured the garbage, they would give him an impulse to the side of the earth, which would reduce the orbit of the garbage and release it, which would lead to its entry into the atmosphere and combustion. The network itself could return to the designated zone and continue working until the energy reserves are exhausted or a serious breakdown occurs.

There is also the problem of uncontrolled, malfunctioning, decommissioned, but not destroyed satellites that pose an undoubted threat, including AND if various parts, including those dangerous to the life of our planet, would start to fall out. This network could be on duty next to such a satellite, both in a closed and open state, and on command to capture it, then acting on a command or an autonomous program. It could also intercept dangerous parts falling out of such satellites, including autonomously, for which it could include appropriate sensors for detecting such an event (for example, optical or magnetic).

In addition to physical capture in this network, a magnetic and electro-magnetic method of capturing objects is possible.

Since there are objects in space that differ in mass, speed and direction, to increase the efficiency of capture and reduce the likelihood of damage, you can put such networks moving with the corresponding relative speed, direction and with the corresponding size of the network itself, cells and engines, for example, launching networks in series, according to the previously explored situation and catching first fast and large (large cell), and then increasingly slower and smaller objects.

The advantages of this solution:

- simplicity, long shelf life;

- A large selection of network sizes (from tiny to huge) with a variety of parameters and equipment for solving various problems;

- great lightness, small volume and weight, which means you can send a lot of them, as well as to equip them with ordinary ships launched;

- high reliability since due to the design of the network, it is slightly susceptible to possible damage and, even in the event of a break, can remain fully operational;

- the method does not require any scientific and technological breakthrough, but is based on existing technologies and materials, which reduces the time for development and testing;

- all this implies a relatively low cost of implementing this method.

Claims (7)

1. A method for removing space debris from near-Earth space by collecting and removing it from near-Earth orbit, characterized in that an apparatus capable of releasing capsules with self-expanding autonomous mobile networks equipped with controllable maneuverable engines is launched into the cleaned area of near-Earth space after the capsules reach a predetermined speed of movement networks are disclosed, and hit sensors installed on the networks transmit information about an object delayed by the network to an existing control panel Which generates a command for closing network or another method of fixing the captured objects and the inclusion of motors for maneuvering the maneuvering of cleaning debris from the orbit, and the network further placed on the means of magnetic and electromagnetic retention of debris. 2. The method according to p. 1, characterized in that the filled network using maneuverable engines is directed towards the Earth, followed by flooding or flooding of the contents or burning it in the atmosphere. 3. The method according to p. 1, characterized in that the filled network using maneuverable engines is directed away from the Earth with the subsequent conclusion to a higher orbit or to a given point. 4. The method according to p. 1, characterized in that the network carrier capsule further comprises means for detecting space debris. 5. The method according to p. 1, characterized in that the filled network using maneuverable engines is directed towards the Earth, followed by a soft landing made using the existing soft landing system. 6. The method according to p. 1, characterized in that the filled networks using maneuverable engines direct the contents in the right direction, then release the caught, which will move itself in the given direction, and the freed network collects another garbage. 7. The method according to p. 1, characterized in that the released capsule is located in a predetermined area with a closed network in anticipation of a command to begin work on the capture of garbage coming from both its own sensors and external control devices.