RU2000129488A - METHOD FOR CREATING POWERFUL HELIO POWER PLANTS - Google Patents

Claims (5)

1. A method of creating powerful solar power plants, including the absorption of sunlight by a solar-absorbing surface thermally insulated from the environment with a light-permeable coating, heating of air in contact with the solar-absorbing surface, characterized by the inertia of the process in time, the direction of the air into the exhaust pipe and then into the wind turbine, coupled to an electric generator, characterized in that the energy components of the surrounding space, including the heating temperature of the solar-absorbing surfaces including water and soil surfaces covered with a translucent heat-insulating coating, air temperature and humidity in enclosed spaces enclosed between a translucent heat-insulating coating and solar-absorbing surfaces that evaporate moisture and generate additional heat fluxes, the velocity of the surface wind flow passing over the surface of the translucent heat-insulating coating surface of the exhaust pipe and further up, the horizontal atmospheric velocity about the wind flow above the exhaust pipe, the temperature and pressure of the air in the atmosphere above the exhaust pipe, are connected with each other by the resulting high-speed flow of air acting on the wind turbine, for which the contact with the dark surface of the air is heated by the above-mentioned water and soil surfaces in energy interaction with flexible over the water surface helioplastic platforms placed on supports fixed to the surface of the water, while the platforms have a flexible frame with cells filled with breathable and helium-absorbing material, fixed in cells on a flexible frame, forming a closed cavity above the surface of the helioplastic material, communicating with the air exhaust traction pipe, while the flexible frames are fixed relative to the water surface on the supports and relative to the coastline - on the foundation base of the air-exhaust traction pipes, while on the water surface under the helioplastic platform place objects of the agro-industrial complex, and on land in space Exothermic industrial equipment is installed in the adjacent to the exhaust pipe, while the air entering the solar-absorbing platforms is preheated above the surface of a thermally insulated solar pond, to create which part of the reservoir volume is limited on all sides by horizontal and vertical heat-insulating partitions, and covered on the air side a translucent heat-insulating coating, creating a channel above the surface of the water, communicating with the platform air industry.  2. The method according to p. 1, characterized in that it further fill the solar pond with warm water from the surface of the reservoir outside the translucent heat-insulating coating, for which overflow intakes are formed in the upper subsurface part of the solar pond, and plums are formed in the lower bottom part of the pond.  3. The method according to PP. 1 and 2, characterized in that it further concentrates the flow of natural wind, directing it vertically upward along the axis of the exhaust pipe into an additionally formed wind-taking channel around the upper part of the exhaust pipe by forming at least two vertically located walls diverging from each other from the exhaust pipe to the periphery , and the ceiling covering the space between the walls.  4. The method according to PP. 1-3, characterized in that the walls and ceiling are made of translucent material mounted on a flexible rope nets.  5. The method according to PP. 1-4, characterized in that the exhaust pipe is provided with a controlled self-rising superstructure, the inner cavity of which is a continuation of the exhaust pipe and which perceives such dynamic energy flows as a stream of heated air leaving the upper opening of the exhaust pipe, a concentrated surface flow of natural wind and the atmospheric flow of natural winds converted into dynamic vertical wind flows, for which the superstructure is performed in the form of a truncated expanding upward of the cone of a flexible bellows in the horizontal sections of airtight material and fix its lower base with respect to load-bearing structures of the upper closure shell Air Release tube or related components.