RU2481252C1 - Balloon-space power supply system - Google Patents

Abstract

FIELD: transport.

SUBSTANCE: invention relates to systems intended for power supply of ground objects from space. Power supply system comprises, at least, one space solar power station 1, ground control station 2 with accumulation system 3, and intermediate power reception station composed of controlled tethered balloon. Solar photo converters 5 and lasers 6 are arranged on the surface of balloon 4 for guidance to space power station 1 while on side facing the Earth IR converters 7 are arranged. Balloon 4 is preferably shaped to disc retained above clouds by cable 8 connecting it with ground system 3. Motors 9 connected with service module 10 are mounted on side surface of balloon 4. Cable 8 is connected with the system of balloon gas bags 11. Space solar power station 1 represents the Earth satellite composed of self-contained photo converting modules, focusing mirror system, super condensers, and remote power transmission system. Besides, it comprises instrumentation-propulsion module with control systems and data exchange system.

EFFECT: higher power production efficiency.

4 cl, 3 dwg

Description

The invention relates to energy supply systems, namely terrestrial consumers from space.

Space solar power plants are known for providing electric power to terrestrial consumers, including a solar power installation and a system for remotely transmitting energy to the Earth in the form of microwave or laser radiation (patent application RU No. 94032672/11 of 09/08/1994, B64G 9/00; patent for invention RU No. 2094334 from 04/18/1994, B64G 1/44, K. Getland, "Space Technology", M., ed. Mir, 1986, pp.228-237). The disadvantages of these power plants are:

1. A large-sized design that cannot be transferred to the orbit as a whole at one time, requiring a large number of launch vehicles and complex and expensive assembly in space;

2. A multistage system for converting solar energy with equipment with large weight and size parameters and a complex and heavy cable network, increasing the risk of failure of individual nodes and, in extreme cases, the equipment as a whole;

3. When using a laser beam as a method of energy transfer, the absence of an energy reception point above the cloud zone will lead to the loss of part of the radiation in the troposphere and, consequently, to a decrease in the process efficiency.

4. When using a microwave beam as a method of energy transfer, which has significant divergence, its area on Earth will reach large sizes, which requires the creation of the same dimensions of the receiving rectenna, which leads to both a rise in the cost of the power plant and a decrease in the efficiency of the receiving elements of the rectenna, which leads to a decrease in the efficiency of the power plant, an increase in the area occupied by the ground-based energy reception point, as well as to a deterioration of the environmental safety of the irradiation zone at the location of the rectena;

Also known are solar power plants located on tethered aircraft lighter than air, on the surface of which flexible solar cells are applied, and the devices themselves are located above the cloud layer (invention patents: RU No. 2377440 dated 06/18/2008, F03G 6/00; RU No. 2389900 from 03/16/2009, F03G 6/00). The disadvantages of these power plants are:

1. The spherical shape of the balloon, leading to the inefficient use of photoconverters and, as a result, a decrease in the efficiency of the process of generating electricity;

2. The use of film photoconverters with their physical nature low efficiency;

3. Daily carrying out the operations of winding onto the drum and unwinding the cable from it, which significantly increases the risk of an accident and wear of the unit.

4. Use only solar radiation to generate electricity.

The closest is, taken as a prototype, a system of power supply of terrestrial consumers from space, including at least one space solar power station and a ground-based point for receiving energy transmitted from space solar power stations (copyright certificate SU No. 946372 of 10.31.1980, H01J 17/00, B64G 1/10). The disadvantages of this system are:

1. The presence of a space power station and a separate space repeater or flotilla of separate space power plants with passive transponders that redirect energy significantly complicate and cost the implementation of this power station;

2. When transmitting energy using a microwave beam with significant divergence directly to the Earth, its area on the Earth will reach large sizes, which, as mentioned above, requires the creation of the same dimensions of the receiving rectenna, which, in turn, leads to a rise in price power plants, and to reduce the efficiency of the receiving elements rectenny, and, accordingly, leads to a decrease in the efficiency of the power plant, an increase in the area occupied by the ground power reception point, as well as to a decrease in environmental safety awns irradiation zone in place recto location;

The technical solution according to the invention is aimed at achieving a technical result, which consists in increasing the amount of electricity received at a smaller size of the ground receiving point, as well as in improving environmental friendliness in the area where the specified point is located.

Below, when disclosing the essence of the invention and describing its implementation and use, including in particular cases of execution, other types of technical result achieved will be named.

The specified technical result is achieved by the fact that, as in the well-known, taken as a prototype, energy supply system, including at least one space solar power station and a ground-based point for receiving energy transmitted from a space solar power station, the proposed aerostatic-space power system equipped with an intermediate point of energy reception, which is an aircraft lighter than air in the form of a controlled tethered balloon, with the service module mounted on it I balloon. Solar photoconverters, for example, three-stage nano-heterostructure photoconverters, and a laser directed to a space power station are located on the surface of this apparatus, facing away from the Earth’s surface. Infrared photoconverters and the aforementioned service module are located on the surface of the aerostat facing the Earth’s surface, while the aerostat is fixed above the cloud zone via a cable cable connected to the ground receiving station. The tethered balloon is made disk-shaped and electric motors are evenly mounted around the perimeter of its side surface (the best option is four), connected to the service module. On the cable cable emerging from the service module, weightless balloon shells are sequentially fixed. A space solar power station is an orbiting satellite consisting of autonomous (independent) photoconverting modules focusing the beam to the Earth, a mirror system, supercapacitors, a remote energy transmission system, an instrumentation module with control systems, as well as systems for receiving control commands and providing information on the status of the satellite to a ground station.

The specified implementation of the energy system using an intermediate receiving ground station in the form of an aircraft lighter than air (a tethered balloon), mounted at a height above the level of clouds, allows not only to receive energy from a space power station, but also, due to the location of three-stage heterostructured and more infrared photoconverters than on a spherical surface to increase the generation of electricity from solar radiation, and e use the energy of the Earth's heat radiation. Location above ground level allows you to reduce the area occupied by the ground receiving point, in addition, the clouds located below the aircraft do not cover the photoconverters located on its surface, and they generate energy coming from the sun, all daylight hours go, in addition, clouds do not scatter laser radiation from a space solar power station. The use of a cable-cable allows avoiding significant losses during energy transfer, as well as destabilizing the stability of the aircraft itself - an aerostat, and the placement of additional balloon-shells on the latter is also aimed at weighting the cable-cable. In addition, the uniform arrangement of electric motors around the perimeter of the balloon-shaped balloon-shaped shell allows maintaining a static state of the intermediate receiving point (for example, in the wind) and ensuring its inclination tending to normal with respect to the laser radiation from a space solar power station. The proposed implementation of the system can significantly reduce the area of its ground segment, while significantly increasing the amount of electricity received (laser radiation from a space station, solar radiation and infrared radiation from the Earth).

The invention is illustrated by drawings, which show:

- figure 1 - aerostat-space energy system;

- figure 2 - aerostat with photoconverters;

- figure 3 is a ground segment of the system.

The proposed aerostat-space power system includes at least one space solar power station 1, a ground-based power receiving point, including a ground control point 2 of the power system and a storage system 3, as well as an intermediate power receiving point, which is an aircraft lighter than air in the form of a controlled tethered balloon 4. On the aerostat 4 surface facing away from the Earth’s surface, there are solar photoconverters 5 and a laser 6 for guidance on space kuyu power station 1, and on the side facing the surface of the Earth, rasplozhen infrared photovoltaics 7. For the convenience of placing solar cells 5 and 7 aircraft 4 is disc-shaped. In this case, the apparatus 4 is fixed above the cloud zone by means of a cable 8 connected to the ground storage system 3. On the lateral surface of the aerostat 4, electric motors 9 are connected evenly along the circumference, connected to the service module 10 mounted in the center of the lower part of the aerostat 4, in which all control equipment and the balloon diagnostic equipment, cables, as well as the antenna, for receiving control radio signals from a ground station and issuing information about the status of balloon systems (not shown), while and the cable-cable 8, leaving the service module 10, sequentially fixed weightless balloon shells 11. Space solar power station 1 is a satellite placed in orbit, consisting of autonomous (independent) photoconverting modules, focusing the beam on the Earth of the mirror system, supercapacitors, system remote transmission of energy, the instrumentation compartment with control systems, as well as systems for receiving control commands and issuing information about the status of the satellite to ground ground tubing (not shown).

Aerostat-space energy system operates as follows.

After all the diagnostics, preliminary launches and guidance of the aerostat 4 to receive laser radiation from the space power station 1, a radio signal is sent from the ground control station 2 to the head of the space power station 1 about the start of normal operation.

Further, the principle of operation is more conveniently divided into two segments:

Space segment.

When the solar space power station 1 is located in the illuminated part of the orbit, the electric current generated by the photoconverters, which are located in the photo-emitting module, charges the supercapacitors and, in parallel, is powered by a line of diode lasers that serve to pump the fiber laser. Further, through the optical fiber from each photo-emitting module, the radiation arrives in a mirror system located on the head of the solar space power station 1, where it is summed into one laser beam and, after that, is transmitted to the photoconverters 5 located on the upper surface of the aerostat 4.

When the solar space power station 1 is located on the unlit part of the orbit, the electric current necessary to power the line of diode lasers is generated from supercapacitors.

Ground segment.

To maintain stable communication with satellite 1, a laser 6 is used to aim at the space power station 1 and electric motors 9, which support the balloon 4 in a static position and provide a tilt of the balloon 4 towards satellite 1.

At the illuminated time of day, the photoconverters 5 located in the upper part of the aerostat 4 process the energy of the sun and the laser radiation coming from the space power station 1. The infrared photoconverters 7 located on the lower part of the aerostat 4 process the heat coming from the Earth’s surface. Further, all the electric current flows through the cable-cable 8 to the drives of the system 3 located on the Earth.

At the unlit time of the day, the photoconverters 5 located in the upper part of the aerostat 4 process the laser radiation coming from the comic power station 1. The photoconverters 7 located on the lower part of the aerostat 7 process the heat coming from the Earth’s surface. The equipment located in the service module 10, provides diagnostics, transmission of signals from the aerostat to the ground control station and ensures the operation of electric motors 9.

This ensures round-the-clock operation of the hybrid solar space power station.

Thus, the proposed design of the aerostat-space energy system through the introduction of an intermediate power receiving point of the above design, has significantly reduced the area of the ground segment of the energy system, significantly increasing the amount of electricity received (laser radiation from a space station, solar radiation and infrared radiation from the Earth ) In addition, this energy system can be used not only on Earth, but also in the development of other planets.

Claims (4)

1. Aerospace-space power system, comprising at least one space solar power station and a ground receiving station for energy transmitted from a space solar power station, characterized in that the system is equipped with an intermediate point for receiving energy, which is an aircraft lighter than air in the form of controllable a fixed balloon with a service module mounted on it, while on the surface of the said apparatus, facing away from the Earth’s surface, there are solar photographic devices photoelectret and the laser directed at a space solar power station, and on the surface facing the surface of the Earth, arranged infrared photovoltaics and said service control module balloon, said balloon is mounted above the cloud zone through wire cable connected to the ground power receiving point. 2. The aerostat-space power system according to claim 1, characterized in that the aircraft is lighter than air in the form of a disk, and electric motors connected to the service module are uniformly mounted around the perimeter of its side surface. 3. The aerostat-space energy system according to claim 1, characterized in that between the service module and the ground-based power receiving point on a cable-cable leaving the service module, weightless balloon shells are sequentially fixed. 4. The aerostat-space energy system according to claim 1, characterized in that the space solar power station is an orbiting satellite, consisting of independent photoconverting modules, a focusing beam of a mirror system, supercapacitors, a system for remote energy transfer, an instrumentation compartment with control systems, as well as systems for receiving control commands and issuing information about the status of the satellite to a ground station.

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