RU2681282C1 - Vortex extractor of atmospheric moisture - Google Patents

Abstract

FIELD: technological processes.SUBSTANCE: invention relates to the field of obtaining fresh water from atmospheric air. Device includes the supply of atmospheric air to the compressed air power generators, the sub-cooling of a flow of compressed and concentrated air flow with deposition and removal of moisture. Extractor consists of carrying case in the form of a conical tube (1), with vortex air ejectors (2) built into its at the inlet and installed uniformly along the length of the case. Each ejector (2) is connected to its own self-vacuuming vortex tube (3) located in case (1) of the extractor. Before each self-vacuuming vortex tube (3), except for the first one, swirled flow diffuser (5) is installed. Copper rod (4) is built along an axis of the case and along its entire length, which serves as a cooler. Hemispherical grooves are formed on the surface of rod (4) along the entire length, which significantly intensify the heat exchange processes. Cooling elements (6) of heat pipes are installed at the ends of rod (4). End side of case (1) of the extractor is made in the form of an isogradient diffuser with vortex deflector (9) at the top and moisture collector (10) at the bottom. Distances Lve between vortex air ejectors (2) installed along the length of case (1) of extractor depend on the diameter Dve of ta place of the case (1) in which these ejectors are installed (2) and is equal to Lve≈(8÷10) Dve.EFFECT: creation of a simple installation with an increased productivity of obtaining fresh water from atmospheric air is ensured.1 cl, 1 dwg

Description

The invention relates to the field of producing fresh water from atmospheric air.

Atmospheric air is a giant reservoir of moisture, and even in arid regions it usually contains more than 6-10 g of water per 1 m ³ . Getting water from air by condensing it on a cold surface has been known since antiquity. Even in ancient times in the Crimea, in order to provide water to the city of Feodosiya, embankments from rubble in the form of a pyramid were used, which were built on a low mountain plateau. Due to the difference between the day and night ambient temperatures, condensate formed on the rubble surface and drained into a special container. From there, he naturally entered the trench through the gutter. There is a great future for the method of extracting water from atmospheric air using natural energy factors.

There is a method of producing water from air, which consists in forming an air stream containing water vapor, cooling it to a temperature below the dew point, condensing water vapor in water, and dehydrated air is emitted into the atmosphere (US patent N 5203989, Е03В 3/28 , 1987). When pumping a stream of atmospheric air containing water vapor, they condense on the cooling element of the chiller and at the same time cool the air stream that is released into the atmosphere. To pump the flow of atmospheric air, a compressed air energy generator is required, which requires external energy.

The disadvantages of this method, which also involves the use of external input energy for the operation of the refrigeration machine, are the low cost-effectiveness of using the cooling capacity of the machine, since only a small part of the energy consumed by it is used to condense water vapor. Moreover, most of the cooling capacity is spent on cooling dehydrated air discharged into the atmosphere.

The well-known energy tower operating on the Maysotsenko cycle with indirectly evaporative air cooling (http://sssrregion.ru/pics/Khalatov, Ukraina.pdf, A. Khalatov, I. Karp, B. Isakov. Maysotsenko cycle and prospects for its use in Ukraine). The energy tower consists of two vertical concentric cylinders. The outer surface of the inner cylinder is covered with a thin layer of a hydrophobic capillary-porous surface wetted by water. Atmospheric air enters the inner cylinder - a dry channel, where it moves downward, being cooled from the cold wall of the channel, the temperature of which decreases due to the evaporation of water from the capillary-porous surface on the outside of the inner cylinder. The cold air emerging from it enters the annular wet channel and moves upward with an increase in its humidity due to the evaporation of water at the outlet of the wet channel. Due to the evaporation of water in the annular wet channel, the mass of the air stream at the outlet of the wet channel is greater than its mass at the entrance to the dry channel. The lowest air temperature close to the dew point is achieved in the lower part of the tower at the outlet of the dry channel. Due to the humidification of the air in the wet channel, its pressure decreases and a lifting force arises, which provides air movement through the dry and wet channels with an increase in its speed. The kinetic energy of the air flow is used to generate electricity by a wind generator installed in the lower part of the dry channel.

A disadvantage of the known installation is the bulkiness of the structure and the non-use in it of the extraction of moisture from atmospheric air.

The closest in technical essence to the present invention is a device for producing water from atmospheric air and generating electricity (RF patent No. 2620830, IPC EV 03/28, publ. 05/30/2017). The device includes two concentrically arranged vertical cylinders that form the “dry” and “wet” air channels, the “wet” channel is provided with a hydrophobic capillary-porous surface wetted by water, a wind power installation, the “wet” channel is placed in the inner vertical cylinder, and it is hydrophobic a capillary-porous surface is attached to the inner wall of the inner cylinder, and a concentric "dry" channel is placed between the outer and inner vertical cylinders, in the lower part of the outer its cylinder has a water tank for collecting condensed moisture, a droplet trap and several rows of moisture drain plates into the water tank with gaps between the plates for air flow, while the water tank is connected by an irrigation pipe to the pump with the upper part of the hydrophobic surface, and it is connected to the consumer with a fresh water discharge pipe, a movable Venturi pipe body, equipped with a wind vane, is installed using bearings on a vertical vertical cylinder above the inner vertical cylinder, and on the central the axis of the Venturi pipe is a wind power installation with a wind wheel and an electric generator, and the body of the Venturi pipe is surrounded by a fixed annular air nozzle mounted on an internal vertical cylinder.

A disadvantage of the known device is the impossibility of organizing the process of extracting moisture from the atmosphere without electricity, the presence of a pump for pumping water and a water wetting system for a hydrophobic-capillary-porous surface. All this makes the device complex, cumbersome and increases the cost of water obtained.

The objective of the invention is the creation of a simple and cost-effective installation with increased productivity for fresh water from atmospheric air.

As a result of the use of the present invention, the costs of producing fresh water from atmospheric air are reduced by eliminating the supply of electricity and the use of vortex energy technologies to create vortex air flows inside the installation, increasing the condensing surfaces, and also significantly increasing the condensing surfaces due to the presence of dehumidifiers - heat exchangers and copper a rod that serves as a cold store, additional cooling of condensing surfaces the rest using heat pumps, as well as the low cost of the vortex elements of the plant structure and the materials from which they are made.

The above technical result is achieved in that the proposed vortex extractor of atmospheric moisture, including the supply of atmospheric air to the energy generators of compressed air, cooling the flow of compressed and concentrated air flow with precipitation and selection of moisture, according to the invention, consists of a supporting body in the form of a conical pipe, with built-in into it at the entrance and vortex air ejectors installed uniformly along the length of the casing, each of which is connected to its self-evacuating vortex tube, p besides the first one, a swirl flow swirl is installed in front of each self-evacuating vortex tube, in addition to the first one, a copper rod is installed along the body axis and along its entire length, which serves as a cold store, on the surface of which hemispherical depressions are formed along the entire length, which significantly intensify heat transfer processes, cooling elements of heat pipes are installed on the ends of the copper rod, the end side of the extractor housing is made in the form of an isogradient diffuser with a vortex the deflector at the top and the moisture collector at the bottom, the distances Lwe between the swirl air ejectors installed along the length of the extractor casing depend on the diameter Dwe of the housing where these swirl air ejectors are installed, and is equal to Lwe≈ (8 ÷ 10) Dwe, the geometric parameters of hemispherical recesses h, Dl and Z on the surface of a copper rod are determined from the relations:

h = 0.2⋅r,

where h is the depth of the hemispherical recess;

r is the radius of the hemispherical recess,

Dl = 2h / tgaα / 4,

where Dl is the diameter of the hemispherical recess;

h is the depth of the hemispherical recess;

α is the fundamental angle of the hemispherical recess, with 45 ° <α <180 °,

Z ~ 10⋅h,

where Z is the distance between hemispherical recesses;

h is the depth of the hemispherical recess.

The invention is illustrated in the drawing, which shows a General diagram of a vortex extractor of atmospheric moisture.

The vortex extractor of atmospheric moisture consists of a supporting casing in the form of a conical pipe 1, with vortex air ejectors 2 integrated into it at the inlet and installed uniformly along the length of the casing (RF patent No. 2093702, IPC F03D 3/04, publ. 10/20/1997, Bull No. 29), each of which is connected to its self-evacuating vortex tube 3 (Merkulov F.P., Vortex effect and its application in technology, Samara, 1997, pp. 26-62, 105-109) located in the housing extractor, before each self-evacuating vortex tube 3, except the first, a swirl 5, along the axis of the housing 1 and along its entire length, a copper rod is built-in, which serves as a cold store 4, on the surface of which hemispherical depressions are formed along the entire length (USSR author's certificate No. 247е98, 1987), which significantly intensify heat transfer processes at the ends of the copper rod 4 cooling elements 6 of heat pipes 7 are installed, the end side of the extractor housing 1 is made in the form of an isogradient diffuser 8 (Volov V.T., Calculation method for a vortex diffuser device, IFZh, 1983, No. 1. S. 35-41) with a vortex deflector at the top 9 and a moisture collector 10 at the bottom.

Vortex extractor of atmospheric moisture works as follows.

Atmospheric air (wind) enters the vortex air ejectors 2 and the vortex deflector 9, in the vortex ejectors 2 the air stream is converted into a concentrated swirling stream, which is supplied to the self-evacuating vortex tubes 3 and creates a zone of reduced pressure inside the housing 1 in the axial region, which leads to the occurrence of very high cooling effects, this cold perceives and accumulates a copper rod (cold store) 4, which is actively promoted by hemispherical recesses (holes) formed on the surface and a copper rod - substantially intensifying heat transfer processes, the swirling flow, giving its energy to the cold storage device 4, enters the swirl 5, which simultaneously acts as a heat exchanger-condenser, and straightened, continues to move along the extractor body to the next self-evacuating vortex tube, the ends of the copper core are installed cooling elements 6 of heat pipes 7, which additionally cool the copper rod 4 with their energy, condensed moisture from the reamers and from the rod flows into o moisture accumulator 10, and the dried air with the help of an isogradient diffuser 8 enters the vortex deflector 9 and is released into the atmosphere.

Claims (11)

Vortex extractor of atmospheric moisture, including the supply of atmospheric air to the compressed air energy generators, cooling the compressed and concentrated air flow with precipitation and moisture extraction, characterized in that the extractor consists of a supporting body in the form of a conical pipe, with an inlet installed in it and installed uniformly along the length of the casing by vortex air ejectors, each of which is connected to its self-evacuating vortex tube, located in the extractor casing, in front of each self-vacuum in addition to the first one, a swirl flow swirl is installed, along the body axis and along its entire length a copper rod is built-in, which serves as a cold store, on the surface of which hemispherical recesses are formed along the entire length, significantly intensifying heat transfer processes, cooling elements are installed on the ends of the copper rod heat pipes, the end side of the extractor case is made in the form of an isogradient diffuser with a vortex deflector at the top and a moisture collector at the bottom, distances Lwe m Between the swirl air ejectors installed along the length of the extractor casing, they depend on the diameter Dwe of the housing where these vortex air ejectors are installed and is equal to Lwe≈ (8 ÷ 10) Dwe, and the geometric parameters of the hemispherical recesses h, Dл and Z on the surface of the copper rod are determined from the ratios: h = 0.2 ÷ r, where h is the depth of the hemispherical recess; r is the radius of the hemispherical recess, Dl = 2h / tgaα / 4, where D _l is the diameter of the hemispherical recess; h is the depth of the hemispherical recess; α is the fundamental angle of the hemispherical recess, with 45 ° <α <180 °, Z ~ 10⋅h, where Z is the distance between hemispherical recesses; h is the depth of the hemispherical recess.

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