RU2013138983A - HELIO-ENERGY STRUCTURE WITH WATER EXCHANGE FUNCTION - Google Patents

Abstract

1. A solar energy structure with a water exchange function, including: one or more greenhouse structures, at least one of which has a double roof, consisting of two partially or completely transparent coatings, which are separated by space with the possibility, due to the roof structure, of simultaneous oncoming water movement sprayed in this space and flowing from top to bottom, and air rising from bottom to top, in the same space between the coatings where the solar-thermal heat exchanger is located, It offers the qualities of a heat exchanger and a solar collector, in which the function of cooling air in a building with cold water is combined with the function of collecting and transfer of solar thermal energy to a water-filled heat accumulator — a tank buried in the ground that is divided into isothermal regions communicating through convection channels formed by the structural form of the heat accumulator or by heat-insulating screens, with the possibility of maintaining in it, at the boundaries of isothermal regions, a temperature gradient and water, by transferring heat energy transferred by water and (or) air depending on temperature to the corresponding isothermal areas of the heat accumulator, the upper isothermal areas of the heat accumulator are insulated by heat shields, and the lower regions are located at deeper levels underground with the possibility of good thermal contact with the ground ; ventilation system that communicates with the space between the coatings, which can function, both due to natural and forced draft, us

Claims (25)

1. A solar energy structure with a water exchange function, including: one or more greenhouse structures, at least one of which has a double roof, consisting of two partially or completely transparent coatings, which are separated by space with the possibility, due to the roof structure, of simultaneous oncoming water movement sprayed in this space and flowing from top to bottom, and air rising from bottom to top, in the same space between the coatings where the solar-thermal heat exchanger is located, It offers the qualities of a heat exchanger and a solar collector, in which the function of cooling air in a building with cold water is combined with the function of collecting and transfer of solar thermal energy to a water-filled heat accumulator — a tank buried in the ground that is divided into isothermal regions communicating through convection channels formed by the structural form of the heat accumulator or by heat-insulating screens, with the possibility of maintaining in it, at the boundaries of isothermal regions, a temperature gradient and water, by transferring heat energy transferred by water and (or) air depending on temperature to the corresponding isothermal areas of the heat accumulator, the upper isothermal areas of the heat accumulator are insulated by heat shields, and the lower regions are located at deeper levels underground with the possibility of good thermal contact with the ground ; a ventilation system in communication with the space between the coatings, which can function, both due to natural and forced draft, water pumps; characterized in that the structure is connected by inlet and outlet pipes and (or) a gutter with a pond (s), a pond (s) or a pool (s) located outside or (and) inside it, directly and (or) through its water part - a floating greenhouse construction, the base of which consists of pontoons and (or) at least three tanks or pools of waterproof material, the level of filling them with water ensures buoyancy of the water part, and their location allows the distribution of water in them, through the leveling distributor , level the water part of the structure, water from a reservoir or pond through floating solar collectors or solar collectors, which are structurally combined with solar panels, and (or) a surface heat exchanger, after cleaning and heat exchange, can enter or flow through the receiving temperature distributor into the heat accumulator of the structure, located in its ground part; and water taken through the intake temperature distributor from the corresponding isothermal region of the heat accumulator, after heat exchange with air in a solar-heat or mixing heat exchanger, where the heat exchange is combined with aeration of the water, can be discharged into the same reservoir from which it was taken either into the arc, directly or through a surface heat exchanger consisting of an external trough along which a pipe or other trough of a smaller diameter is located in its inner region, heat exchanger is possible in this heat exchanger varied through the thermally conductive material pipe or chute, which separates the water withdrawn from the supply air. 2. The solar energy structure according to claim 1, characterized in that the leveling distributor for water is two hollow cylinders coaxially arranged in one another with a minimum clearance and connected by an axis through the rotation support coaxial to the central axis of rotation with the possibility of rotation of the inner cylinder relative to the outer one around this an axis of rotation controlled by a level sensor, a rotary means, with which the inner cylinder is connected by a shaft or axis, coaxial with the Central axis of rotation; through holes are made in the cylinders, the area of each of which is at least four times smaller than the cross-sectional area of the inner cavity of the distributor with a plane perpendicular to the axis of rotation, while the center of the hole in the inner cylinder lies in one plane of the cross section with the center of the hole aligned with it in outer cylinder, the discreteness parameter of the distribution is the alignment angle, that is, the angle, relative to the axis of rotation, by which the inner cylinder must be rotated for synchronous displacements: one opening of the inner cylinder is aligned with the opening of the outer cylinder them connected pipe with a specific capacity, and the other opening of the inner cylinder to combine them with another opening of the outer cylinder tube connected to the pump; it differs from the same angle for aligned holes related to any other container, at least by the diameter of the hole, expressed in arc degrees, counted along the arc of the boundary circle formed in the cross section of the distributor between the outer and inner cylinders by a plane perpendicular to the axis of rotation, this the angle is functionally related to the readings of the level sensor controlled by the rotary means. 3. The solar energy facility according to claim 1, characterized in that the intake or intake temperature distributor for water consists of two hollow cylinders coaxially arranged in one another with a minimum clearance and connected by an axis through the rotation support coaxial to the central axis of rotation with the possibility of rotation of the inner cylinder relative to external around the same axis of rotation controlled by a temperature sensor, a rotary means with which the inner cylinder is connected by a shaft or axis; through holes are made in the cylinders, the area of each of which is at least four times smaller than the cross-sectional area of the inner cavity of the distributor with a plane perpendicular to the axis of rotation, while the center of each hole in the inner cylinder lies in the same plane of the cross section with the center of the hole aligned with it in the outer cylinder, the discreteness parameter of the distribution is the alignment angle, that is, the angle, relative to the axis of rotation, by which the inner cylinder should be rotated, for synchronization combination: at least one bore of the inner cylinder with at least one bore of the outer cylinder that is connected to or connected to a particular isothermal region of the heat accumulator, and another bore of the inner cylinder with another bore of the outer cylinder that is combined with it - a supply pipe with a mixing heat exchanger or a pump, it differs from the same angle for compatible openings related to any other isothermal heat storage region Yator, at least on the hole diameter, expressed in degrees of arc, measured along the arc of the boundary circle formed in a cross section of the distributor between the outer and inner cylinder plane perpendicular to the rotational axis, this angle is operatively associated with temperature sensor readings controlled pivoting means. 4. The solar energy facility according to claim 3, characterized in that the receiving or (and) intake temperature distributor is located inside the heat accumulator, its height is commensurate with the total height of the isothermal regions of the heat accumulator, the distributor, like its central axis, is vertically installed in the heat accumulator through the corresponding its outer diameter of the hole in the insulating screens, while the outlet openings of the distributor corresponding to certain temperature values are distributed water, are located in their respective areas of izotemperaturnyh temperature water tank. 5. The solar energy facility according to claim 2 or 4, characterized in that the intake pipe of the distributor is supplied not through a window in the side surface of the cylinder, but from one of the bases of the inner cylinder, which has windows and with sufficient clearance to the base of the outer cylinder so that the pipe brought to it, connecting the distributor to the pump or heat exchanger, does not prevent it from turning to the maximum angle for the given design, or instead of the inner cylinder, a pipe connected to the a rotary shaft and a rotation support with openwork fasteners or consisting of separate elements that do not impede the penetration of water into the distributor. 6. The solar energy structure according to claim 1, characterized in that the mixing heat exchanger located in the space between the roof coverings or the facade walls in the basement area of the structure is a horizontally extended along one or more sides of the structure air duct with a waterproofed pallet connected to the outlet pipes for a pipe for draining water from the sump to the surface heat exchanger and (or) a reservoir, inside the duct above the sump there is a pipe with nozzles for spraying and / or sprinkling water, under Vai pumped through intake valve temperature water from the corresponding inlet air temperature requirements izotemperaturnoy heat storage region, the duct housing has a window or branch communicates with ventilation windows inner region structures with one hand and ventilation ducts and (or) the space between the other coatings. 7. The solar energy facility according to claim 1, characterized in that the outer casing of the mixing heat exchanger is made of a transparent material or has a partially transparent surface, it has the shape of a rounded pipe and may have the following shape in cross section: round, quadrangular, triangular, oval, or a combination of these figures, it is divided by at least one longitudinal horizontal and (or) inclined surface, permeable to water and air, for example, mesh, at least in two parts: in the uppermost part of the ozhena tube with nozzles and laterally in two levels above the dividing surface and beneath it, arranged sealable window to allow the passage of air involved in heat exchange, at least two of the heat exchanger. 8. The solar energy facility according to claim 6 or 7, characterized in that the fans are installed with the possibility of reversing on the sides of the housing of the mixing heat exchanger in the ventilation windows, and the valves with filters of different densities are installed in the windows of the outlet ventilation, automatically blocked partially or completely from the drive, processor controlled. 9. The solar energy structure according to claim 1, characterized in that the space between the roofs of the pitched or tent roof or the outer and inner walls of the facade of the structure with double walls is also divided by the space, in the structure of the structure the space between the roof coverings is combined with the space between the walls of the facade, it is reported with the internal space of the structure through the ventilation windows in the upper and lower levels of the internal coating and (or) in the internal walls of the facade, in the space between the coatings a solar-thermal heat exchanger consisting of: a pipe with nozzles for spraying water on the upper part of the inner coating below the level of the upper ventilation windows, a drainage gutter adjacent to the cornice of the inner coating, or a cornice of the inner coating, made in the form of a gutter that is located above the lower ventilation windows, drain pipes for draining water flowing under the influence of its own gravity: first, on the frame of the inner coating and (or) on the inner coating, and then through the surface heat exchanger in the pond or through a distributor in the heat accumulator. 10. The solar energy structure according to claim 1, characterized in that the structure has a gable double roof, the space between the coatings of which is combined with the space between the double walls of the facade, while part of the external roof covering above the basement between the low double walls has the form of transparent transparent frames, fixed on hinges or in guides and creating access to the space between the walls or coatings of the basement of the structure, where the surface and mixing heat exchangers are located. 11. The solar energy structure according to claim 1, characterized in that the surface heat exchanger is located in the basement of the structure, in the space between the coatings or walls, the outside of which is partially or completely transparent, and includes: filtering and disinfecting devices, an external chute with a cylindrical reflective surface , through which aerated water is removed from the solar-thermal or mixing heat exchanger, which is in thermal contact with the supply water heated by the sun, blackened by the supply pipe oh situated within the trough along its focal axis, the trough connected to the outlet pipe and the pipes leading from the heat exchanger and mixing (or) the solar-heat exchanger. 12. The solar energy structure according to claim 1 or 11, characterized in that the surface heat exchanger located along the perimeter of the structure includes a blackened outer chute, closed by a transparent cap and heated by the sun, through which water in thermal contact with the pipe enters or flows, discharging aerated water after mixing or solar-thermal heat exchange, which is located inside the trench along its length, one end of this pipe is connected to pipes leading from the mixing heat exchange ika and (or) solar-thermal heat exchanger, and the other with a pond. 13. The solar energy facility according to claim 1, characterized in that the heat accumulator consists of modules connected to each other, consisting of pipe crosses, each of which is formed as the intersection of three pipes located along the coordinate axes: x, y, z, that is, six connections, and connected to six neighboring, except for pipe crosses located on the outer boundary surfaces of the heat accumulator, which consist of five pipe connections or sixth connections, interconnected by horizontal pipes or pipes; the pipes located along the x and y axes lying in horizontal planes form the isothermal regions of the heat accumulator, the pipes with the heat-absorbing substance are located in them, and the pipes along the vertical z axes have, on one side, a pipe inner diameter equal to the depth of the connection, equal to external from the opposite side of the module and (or) fixing protrusions for fixing heat-insulating screens with convection channels. 14. The solar energy structure according to claim 1, characterized in that the heat accumulator is located in the waterproofed basement under the structure, the lower part of the basement, at the level of one or two lower isothermal zones, is filled with water, in which the pipes of the lower isothermal regions of the heat accumulator are located, they diverge in spirals or zigzag from the central heat accumulator, occupying a large area of the basement bottom, between the turns of the spiral or zigzags of pipes of the lower regions of the heat accumulator, the sections are laid out of the heat-intensive stone heat insulating partitions, rises above a stably regulated water level in the basement, separating partitions function as supports for a thermally insulated floor, under which a labyrinth of channels is formed between the floor, water and separating partitions, which is an air duct and a heat exchanger for air. 15. The solar energy structure according to claim 1, characterized in that the outer part of the heat accumulator is made as a moat with step-shaped walls, it is located around the perimeter under the basement region of the space between the coatings, at least on one side of the structure, steps or ledges a support for heat-insulating screens, forming a division of the outer part of the heat accumulator into isothermal areas. 16. The solar energy facility according to claim 1, characterized in that the lower isothermal regions of the outer part of the heat accumulator are connected by pipes equipped with valves controlled by floats or electromagnets to the basement of the central heat accumulator, while water from the lower regions of the outer part of the heat accumulator enters the basement in an amount equal to taken from the basement for heat transfer; and the upper warm isotemperature regions of the outer part of the heat accumulator are connected by pipes through an intake temperature distributor or the upper isotemperature region is connected directly to the receiving temperature distributor of the central heat accumulator. 17. The solar energy facility according to claim 1, characterized in that a heat shield with a good reflective surface is located along the outer perimeter of the outer part of the heat accumulator, and, like heat insulating screens for the upper isothermal areas of the outer and central parts of the heat accumulator, consists of a double sheet, for example, metal foils, each of which has a good reflective surface, in a small gap between sheets filled with porous material, a vacuum or vacuum is created, which is maintained by a porous filler material and a binder netted reinforcement sheets forming the honeycomb structure with sealed cells 18. The solar energy structure according to claim 1, characterized in that the structure is located along the crest of the dam of the pond, while the solid base of the heat accumulator and (or) the basement for it serves as a screen and (or) the core of the dam. 19. The solar energy facility according to claim 1, characterized in that the outlet pipe is laid along the bottom and under the dam of the cascade lower in the level of the pond, which consists of at least three adjacent ponds, thereby achieving the possibility of aeration of both the downstream pond and the one following him a cascade pond. 20. The solar energy facility according to claim 1, characterized in that the water part of the structure associated with the ground part of the outlet and supply pipes is located on piles, includes a central water outlet and has a heat exchanger tray or gutter on the inside, the water level in which below the water level of the reservoir, it is connected by a pipe to the deepest region of the reservoir, as well as pipes: inlet with the ground part of the structure on the one hand, and a spillway with a central drain on the other. 21. The solar energy structure according to claim 1, characterized in that the floating water part of the structure, connected by an electric cable to the ground part, has one pile with a hinged-sliding support located in the central part, which is the axis of the rotary support for the bridge on the pontoons connecting the water part structures with a ground one, or the axis of the bridge’s rotary support on the floating part of the floating greenhouse, is fixed by the tension of two cables connecting it or part of the bridge near it with the shore and forming a triangle with a rotary bridge A peak, and a bridge, as the height, edge of the water part, and its orientation is fixed by tensioning the cables connecting the edges of the water part of the structure with two orientation change coils with drives that are located on the shore on opposite sides of the bridge. 22. The solar energy structure according to claim 21, characterized in that the cable or rope fixing the orientation of the water part of the structure is fixed at two points on the shore located on opposite sides of the bridge, passed through blocks, the edge of which are located at remote points on opposite sides of the water part, and wrapped in a loop around the orientation change coil located on the water part of the structure and connected to the sensor-driven drive. 23. Solar energy construction according to paragraphs. 1 or 21, characterized in that the flood part, including floating solar collectors located inside and (or) outside the flood part of the structure, and (or) the flood part itself operates on the principle of a floating solar collector, it is connected to the main structure by a bridge through a rotary support or a rotation support, the ground side of the bridge is fixed on piles or piles, by means of sliding or articulated-sliding supports, as well as outlet and supply pipes with flexible, for example corrugated inserts with a margin in length, defined maximum water level fluctuation in the water body. 24. The solar energy facility according to claim 22, characterized in that the solar collector, structurally combined with solar panels, is a winding heat-conducting tube or coil filled with water, located on a heat-absorbing plate, on the side of which the solar panels are facing the sun, it has the heat-absorbing circuit board has good thermal contact, the lower part of the coil is immersed in water, and the upper part is connected to a heat-insulated hose connected to the water intake pump; or brought into the chute from which the water is drawn, providing a lower level compared to the water level of the reservoir where the lower part of the coil is immersed, one of the sides of the board is hinged in a floating frame, and the other has the ability to be lifted by cables fixed on the far side of the perimeter with respect to the hinges and brought through the blocks located on the beam uniting the structure in the form of two openwork triangles or semicircles located at the edges of the frame, the openwork design of which is support for transparent covering material; or through blocks located on a beam in the ridge region of the water part of the structure, with the location of solar collectors inside it; the opposite ends of the cables are fixed on coils or drums placed on the axis of the traction drive controlled by the sensor with a locking mechanism, by means of which it is possible to lift one of the sides of the collector board and orient it perpendicular to the sun's rays. 25. The solar energy structure according to claim 22 or 24, characterized in that the water part of the structure in cross section forms a semicircle, includes floating solar collectors and (or) solar collectors combined with solar panels, which are assembled in frames, fixed by means of loops on the longitudinal axis, located in the central region of the flood part of the structure, near the longitudinal axis there is a longitudinal component of the network of service bridges, cables or a cable are fixed along the far side of the perimeter and the corners of the frames you, brought through the blocks located in the ridge part of the waterborne structure, the opposite ends of the cables are mounted on coils placed on the axis of the controlled traction drive with a locking mechanism.