RU2146744C1 - Method for producing water from air - Google Patents

Abstract

FIELD: hydraulic engineering. SUBSTANCE: method allows for autonomous producing of fresh water of potable quality from moisture of ambient atmospheric air which can be used for domestic needs and for requirements of national economy. According to method, created is flow of air containing water vapor. Air flow is artificially cooled for condensation of water vapor. Thus produced fresh water or condensate is delivered to water collecting vessel. Cooled air is delivered to condenser for ensuring normal functioning of cooling device. Created air flow is directed through filter of air intake in conditions of ambient medium with relative humidity from 70 to 100% and temperature from 15 to 50 C. Then, air flow is brought through electrostatic field. Obtained cooled air is delivered through connecting skirt to radiator of condenser. Amount of air passing through radiator in conditions of containing 20 g of moisture per 1 cu.m of air and average daily output of unit equal to 250 l of water is within 12-13 cu.m per day. Application of aforesaid method allows for producing fresh water when traditional water sources are not available. EFFECT: higher efficiency.

Description

 The invention relates to methods for autonomous production of fresh water of drinking quality from the moisture of ambient air and can be used in everyday life to meet the needs of the population in purified drinking water, as well as for the needs of the national economy in its industrial use.

 Currently, the task of obtaining fresh water in the absence or inaccessibility of traditional sources is very urgent.

 One of the possible methods for solving the problem is the condensation of water contained in the air.

 Thus, a known method and apparatus for removing water from the air, in which water is removed from the air by repeating the four-stage cycle. At the first stage, the heat storage condenser is cooled with cold air supplied from outside, and the reagent, which increases hygroscopicity, is moistened. In the second stage, water is removed from the specified reagent by a stream of air heated by solar radiation, and it is brought to a heat storage condenser. At the third stage, an additional condenser of heat accumulation is cooled by air coming from outside, and a reagent that increases hygroscopicity is moistened. In the fourth stage, water is removed from the specified reagent by air heated by solar energy / French patent N 2464337, CL. E 03 B 3/28, 1981 /.

 Without detracting from the merits of this method and device for its implementation, it is nevertheless necessary to note its more complex implementation.

 A known method and device for extracting water from atmospheric air, one of which is an air-water generator according to US patent N 5203989 class. E 03 B 3/28, 1987.

 According to this patent, a stream of air containing water vapor is formed, it is cooled to a temperature below the dew point, water vapor is condensed into water, and dehydrated air is released into the atmosphere.

 The known device comprises a housing in which a refrigeration machine and means for transporting an air stream are installed. The lower part of the housing is connected to a condensate collector.

 When pumping a stream of atmospheric air containing water vapor, they condense on the cooling element of the chiller and simultaneously cool the air stream that is released into the atmosphere.

 The known method and device are characterized by low cost-effectiveness of using the refrigeration capacity of the refrigeration machine, since only a small part of it is used to condense water vapor, especially at low air humidity. Moreover, most of the cooling capacity is spent on cooling dehydrated air discharged into the atmosphere.

 A known method of extracting water from air / WO, 93/04764, cl. E 03 B 3/28, 1993 /, which consists in forming a stream of air containing water vapor, performing an artificial cooling of the air stream in one section of the second stream, arranging heat transfer between the parts of the air stream located on both sides of the section of artificial cooling, water vapor condenses in that part of the air stream whose temperature is below the dew point, and emit dehydrated air into the atmosphere.

 In the known method, a single pre-cooling of the incoming air stream is carried out, which improves the efficiency of using the refrigerating capacity of the refrigeration machine.

 At the same time, the complex trajectory of the air flow creates a large gas-dynamic resistance.

 A known installation for producing fresh water from moist air, which uses solar energy / DE 3313711, class. E 03 B 3/28, 1984 /.

 Due to the electricity received from solar panels, the refrigeration unit produces cold, which is released on the heat exchanger-evaporator. Humid air is blown through a fan through the duct in which the evaporator is located. As a result of contact with the surface of the heat exchanger-evaporator, the air cools, the steam contained in it becomes saturated, partially condenses on the surface of the heat exchanger and flows into the water collector.

 The disadvantages of this installation are high energy consumption and low productivity.

 Known installation in which the accumulation of cold for its use at night / EP 0430838, class. E 03 B 3/28, 1991 /.

 In the daytime, electricity from solar panels goes to the refrigeration unit, which produces cold. With the help of a valve, the refrigeration unit is connected to a thermally insulated container. The liquid in it is pumped through the refrigeration unit and cooled by means of a hydraulic pump, as a result, cold accumulates in the thermally insulated container. Then, the thermally insulated container with the help of the valve is disconnected from the refrigeration unit and connected to the heat exchanger-condenser. When the air humidity reaches a value close to 100%, the hydraulic pump and fan are turned on. With their help, cold liquid and moist air are passed through a condenser. Water vapor contained in the air condenses on its surface, and the droplets contained in it are captured by a droplet eliminator and trapped moisture flows into the water collector.

 The disadvantage of this installation is the need for energy consumption and the lack of autonomy during operation of the installation.

 A device for producing fresh water is known, comprising a heat exchange surface on which moisture condenses from the outside atmospheric air and precipitated condensate is collected in a condensate collection vessel. The device comprises a wind energy generator for actuating a circulating installation that removes heat. The heat exchange surface and the wind power generator are located on a floating support structure. The heat removal circulation plant has a heat exchanger located at a certain distance below the surface of the water to use the cold of the deep layers of water / German application N 3319975, class. E 03 B 3/28, 1984 /.

 The disadvantage of this device is the presence of a wind power generator, which leads to design complexity and reduces the reliability of the action, complicates maintenance. The use of a closed cooling water circulation system and the location of the heat exchanger within the immersion depth of the floating support structure does not allow cooling of the circulating water to low temperatures, which reduces the overall efficiency of the device and does not allow for its high performance.

 A device for condensing dew containing a support on which a condensing surface is located is known. The surface is electrically poured from the ground, which ensures the creation of an electrostatic charge on the surface. Under certain climatic conditions, moisture in the air condenses on the surface. There is a collector in which condensate flows from the surface, as well as a device for pumping condensate into the tank. In one design, the condensing surface is made in the form of a vertical metal sheet, and the collector is a channel along the edge of the sheet. The sheet can rotate around the support for installation in the wind. In another design, the condensing surface is made in the form of an inverted cone, divided into triangular segments. Surface area can be increased by ribs. The tank, which can be installed underground, may have a plastic bag of permeable material. The bag is put on the lower end of the condensate feed pipe from the collection / GB 1603661, cl. E 03 B 3/28, 1981 /.

 However, this device is not effective enough in operation due to its high metal consumption.

 The closest technical solution to the claimed combination of features is a method of producing water from air, which consists in forming a stream of air containing water vapor, performing an artificial cooling of the air stream, condensing water vapor, and the resulting fresh water-condensate is fed into a container for water collection / RU 2081256, cl. E 03 B 3/28, 1997 /.

Without detracting from the advantages of the closest method and device for its implementation, the claimed method is still the most industrially applicable, since it has several advantages compared to known traditional methods and installations for their implementation to obtain water from the air, namely:
- gives water of high (rain) quality, which can be stored for a long time;
- ensures environmental cleanliness of operation;
- the installation for implementing the method is transportable, simple and durable in operation, has a weight of 60 kg, small dimensions and cost.

 The objective of the invention is to obtain fresh water in the absence or inaccessibility of traditional sources of condensation of water contained in atmospheric air.

The problem is solved due to the fact that in the method of producing water from air, which consists in forming a stream of air containing water vapor, the air stream is artificially cooled, water vapor is condensed and fresh water-condensate obtained in this way is fed to a collection tank water, and the cooled air - to the condenser to ensure the operating mode of the refrigeration device, the formed air stream is passed through the air intake filter in ambient conditions with relative humidity from 70 to 100% and temperature swarm from +15 to +50 ^o C, and then through the electrostatic field produced cooled air via a connecting skirt fed to the condenser radiator and the volume of air passing through the radiator from the condition 20g moisture per 1 m ³ of air and average daily capacity of the unit up to 250 l / day is in the range of 12-13 thousand m ³ per day.

 The method is implemented as follows: for example, by a fan, a stream of atmospheric air containing water vapor is formed, which, passing through the air intake filter and the electrostatic field with an electric field strength E = 1.5 V, enters the condenser, where it is cooled below the dew point. The resulting fresh water-condensate flows down the drain into a container for collecting water. Cooled air through the connecting skirt is fed to the condenser radiator to ensure the operating mode of the refrigeration device.

The normal operation of the method of obtaining water from air occurs under the following basic environmental conditions:
- relative humidity from 70 to 100%;
- temperature is from +15 to +50 ^o C.

 Water is more efficiently obtained from air in an environment with increased absolute humidity and a significant daily temperature drop.

The limiting (non-working) conditions of the method of extracting water from the air and the installation for implementing the method, in which its operation should be stopped, are:
- lowering the ambient temperature below +15 ^o C;
- increase in ambient temperature above +50 ^o C;
- lowering ambient humidity below 70% at +20 ^o C;
- increasing the dust content of ambient air over 0.5 g / m ³ ;
- the deviation of the capacitor housing from a vertical angle of more than 5 ^o .

 If the method of water extraction occurs directly by the sea, in a coniferous forest or in a flower meadow, then the resulting water will have healing properties.

 Mineralization of the resulting water is achieved in two ways. Simple mineralization - by placing a piece of limestone in a pan or container for collecting water, with the replacement of limestone every five years. Complex mineralization (to create a programmable mineral composition) - by introducing microprocessor and salt containers into the design.

Claims (1)

A method of producing water from air, which consists in forming a stream of air containing water vapor, performing an artificial cooling of the air stream, condensing the water vapor and supplying fresh water-condensate thus obtained to a water collecting tank, and the cooled air to a condenser to ensure the operating mode of the refrigeration device, characterized in that the formed air stream is passed through the air intake filter in ambient conditions with a relative humidity of 70 to 100% and a temperature of +15 to +50 ^o C, and then through the electrostatic field, the cooled air received through the connecting skirt is fed to the condenser radiator, while the volume of air passing through the radiator from the condition of 20 g of moisture per 1 m ^{3 of} air and the average daily productivity of the installation is up to 250 l / day is within 12 - 13 thousand m ³ per day.