RU2117734C1 - Device for producing fresh water - Google Patents

Abstract

FIELD: fresh water producing technology. SUBSTANCE: this relates to producing fresh water from air without using energy from external source and with no harm to ecology of environmental medium. Fresh water producing device has pipeline 1 which is immersed in deep layers of water basin (sea), and vessel 3 which is connected with pipeline and located in surface layer of warm water and connected with this layer of warm water through bottom hole 4. Located in vessel above water surface is air duct 6 with unobstructedly open inlet hole 7 and outlet hole 8. Inlet hole 7 is located above outlet hole 8. Lower wall of air duct which is inclined towards pipeline functions as partition between cooling zone which is located below partition and filled with running cold water and condensation zone which is located above partition within limits of air duct. Additionally installed in system of pipeline-vessel is axial impeller pump, and additionally installed in air duct is axial fan. Movement of water from deep layers is effected through pipeline and vessel due to outflow of cold and more dense water from vessel to zone of more warm and less dense water in surface layer. In this case, system of pipeline-vessel operates like communicating vessel under effect of hydrostatic forces from side of surrounding water. Movement of air in air duct takes place due to cooling of air and increasing its density at coming into contact with cooling partition. Condensate of water steam setting on upper surface of partition which is not wetted with water is collected in fresh water vessel 11. EFFECT: higher efficiency. 5 cl, 1 dwg

Description

 The invention relates to a device for producing fresh water from water vapor contained in ambient air, without the cost of energy from external sources and without any environmental pollution and can be used to produce fresh water mainly in coastal areas with seas.

 A condenser is known that contains a cooled baffle separating the condensation zone of water vapor and cooling water, with the help of this water the baffle is cooled to a lower temperature than the saturation temperature of water vapor at a given pressure and fresh water is obtained (Polytechnical Dictionary / Ed. A. Ishlinsky, Moscow: Soviet Encyclopedia, 1980, p. 235).

 The disadvantage of such a condenser is the need for energy from an external source to cool the partition, on the surface of which condensation of water vapor and water are obtained, and to ensure movement along the back surface of this partition of cooling water, which ultimately leads to environmental pollution of the source of this energy.

 Closest to the claimed combination of features is a device for producing fresh water containing a heat exchange surface on which moisture condenses from the outside air and the condensate that has collected 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, for example, on a raft, ship, etc. 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 N3319975 A1, 1984, class E 03 B 3/28).

 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.

 The present invention ensures the achievement of a technical result, which consists in the absence of the need for energy consumption from an external source when conditioning steam, increasing the reliability of autonomous, continuous and automatic operation with virtually no wear and tear with a minimum number of maintenance (observing) personnel. However, during operation of the device, any environmental pollution is completely eliminated.

 The specified technical result is achieved by using a device for producing fresh water, using the cold of the deep layers of water and containing a heat exchange surface on which moisture condenses from the outside atmospheric air, and the precipitated condensate is collected in a condensate collection vessel. According to the invention, the device comprises a container, isolated in the surface layer of warm water and communicating with the surrounding air, filled with running cold water, supplied through a pipeline connected to the container, which is lowered into the deep cold layers of the water of the natural reservoir and is a communicating vessel with respect to the surrounding water, the upper part of which is located above the level of the surface water layer of the reservoir and freely communicates with the surrounding air, a bottom hole is made in the lower part of the tank, through which free outflow of denser cold water from the tank to the limits of the surrounding surface layer of warmer and less dense water is carried out and a continuous stream of cold water is created through the pipeline and the tank from the deep layers of the reservoir to the surface layer and a heat exchange is installed in this stream within the tank the surface in the form of a partition separating the condensation zone and the cooling zone, one surface of the partition, facing down to the cooling zone, is washed with cold running water, and turned The other surface facing up into the condensation zone communicates with the surrounding air with the possibility of condensation of the water vapor contained therein and is connected to a vessel for collecting water condensate obtained from the surrounding atmospheric air.

 The surface of the partition facing up towards the condensation zone has a non-wettable coating.

 The partition is made in the form of the bottom wall of the duct freely open on both sides and the surface of the partition facing down into the cooling zone is washed with cold water flowing through the tank, while the inlet of the duct is facing away from the pipeline and is located above the outlet of the duct facing the pipeline, which provides air movement through the duct from the inlet to the outlet due to cooling of the air and increasing its density when moving along a cooled surface awn of the septum.

 The partition is placed in a tank with an inclination towards the vessel for collecting water condensate, which is installed at the edge of the partition, facing the pipeline.

 An axial vane pump is additionally installed in the water stream through the pipeline and the tank, which provides increased reliability and an increase in the speed of water in this stream.

 An axial fan is additionally installed within the duct, providing an increase in the reliability of creating an air flow and an increase in the mass of air passing over the partition per unit time.

 The diagram below shows in general terms a device for producing fresh water. A tank with flowing cooling water and an air duct with a partition in the form of its lower wall are shown in section by a front secant plane. Arrows of different lengths and thicknesses show the movement of cooling water, air, and water condensate.

Information confirming the possibility of carrying out the invention is given by the example of sea (ocean) water. It is known that the average annual temperature of the surface waters of the ocean and its seas is 17.5 ^o C, and at the equator - up to 28 ^o C. Moreover, seasonal temperature fluctuations are observed to a depth of 100 - 150 m and in the lower layers it is constant and is about 1 , 5 ^o C. Therefore, the average temperature drop of the oceans between the surface and deep layers is 16 ^o C and the maximum is up to 26.5 ^o C (see the above "Political Dictionary", pp. 920 - 921). This temperature difference determines the greater density of water at a low temperature and its lower density at a higher temperature.

 Communicating vessels are also known in which the property of a liquid is used to move in these vessels in vertical directions, including upward, and to be installed in these vessels in equilibrium with respect to hydrostatic forces acting on the liquid without additional energy costs. Soviet Encyclopedic Dictionary. M .: Soviet Encyclopedia, 1987, p.1245).

 Different density of water at different temperatures in combination with the use of the above properties of communicating vessels allow you to create a continuous flow of liquid in the vertical direction from the bottom up. An inexhaustible source of thermal energy of sea water due to the constant temperature difference of its surface and deep layers provides the implementation of this method of water movement in almost perpetual motion mode, i.e. continuously, without any costs of fuel and energy resources and material resources and without environmental pollution.

A device for producing fresh water (see diagram) contains a freely flowing pipe 1, lowered into the deep layers of sea water with a low temperature T ₁ , the upper part of the pipeline is open, placed above the water level and freely communicates with the surrounding atmospheric air. The specified execution of the pipeline characterizes it as a communicating vessel with respect to the surrounding water, the water level in which depends on its relative density with respect to the density of the surrounding water and is set at an appropriate height under the action of hydrostatic forces without external energy. At the level of the surface-thermal layer of ambient water with a temperature T _{2, a} hole 2 is made in the side wall of the water flowing part of the pipeline, communicating with a container 3, which is isolated in the surface layer of warm water. The upper part of the tank has free communication with the atmosphere and is located above the water level. The internal volume of the tank is isolated from the surrounding water and communicates with its surface layer only through a freely flowing bottom hole 4 in the lower part of the tank. The hole can be combined with a downwardly directed short pipe 5 located in a surface warm layer of water. Within the container 3 and above it, an air duct 6 is installed, having an inlet 7 and an outlet 8 on the opposite sides for free passage of air. The outlet opening is directed towards the pipeline 1. The inlet 7 is facing away from the pipeline 1 and combined with the open pipe 9, the entrance to which is located above the outlet 8 and is freely connected with the ambient air. The bottom wall of the duct 6 is a heat exchange surface, which is made in the form of a heat-conducting partition 10, which defines the internal volume of the duct 6, which is the condensation zone, from the tank 3, which is the cooling zone, which provides cooling of the partition below the saturation temperature of the condensed water vapor. The upper surface of the partition 10 faces the inside of the duct, and the lower surface within the tank is washed by cold running water coming from the pipeline. The partition has an inclination towards the vessel 11 for collecting water condensate, which is installed at the end of the partition, facing the pipeline. The surface of the partition facing up into the condensation zone has a non-wettable coating.

 In the flow of cooling water within the pipeline or tank 3, a pump can be additionally installed (mainly an axial vane pump that has minimal resistance to liquid flow when it is turned off), which increases the reliability of creating a water flow and increases the speed of cooling water washing the bottom surface of the partition 10.

 Within the duct 6, an axial fan can be additionally installed, which increases the reliability of creating an air flow through the duct and increases the mass of air passing over the partition per unit time, which contributes to a corresponding increase in the amount of condensed water.

 A device for producing fresh water works as follows.

 To start the device, using cold water installed in the device or portable auxiliary pump, cold water is forcedly moved from the deep layer through pipeline 1, tank 3 and bottom hole 4 with pipe 5 to the limits of the surrounding surface layer of warmer water. This pump is turned off or removed after filling the entire specified system with cold water from its deepest layer.

The feasibility of creating a water flow in this order is ultimately due to the manifestation of a universal (fundamental) law of energy conservation during the exchange of thermal energy between warm water from the surface layer with temperature T ₂ and water from the deep layer having a low temperature T ₁ , which determines their different density and the possibility of movement of denser cold water through the bottom hole 4 in the lower part of the tank 3 within the less dense warm water in the surface layer. To eliminate interference with the movement of water, the hole 2 in the side wall of the pipeline is larger in area than the bottom hole 4 in the lower part of the tank. Draining water from the top of the pipeline into the tank drives the water in the pipeline from the bottom up under the action of hydrostatic forces from the side of the water surrounding the pipeline. In this case, the rise of water in the pipeline occurs as in a communicating vessel relative to the surrounding water without the expenditure of energy from the outside.

 Combined with the bottom hole 4, the downward facing pipe 5 drains the dense cold water from the tank into the limits of warmer and less dense water from its surface layer and arranges this flow.

The possibility of creating a water flow in the above manner is confirmed by the calculated data. It is known that the density of water is inversely related to its temperature (anomalous deviation at 4 ^o C is not considered here). Based on this, the level of the denser cold water in the pipeline and tank (for example, at 2 ^o C, i.e. at the temperature of the water with which it is supplied from the deep layer) will be lower than that of the surrounding water, the average density of which is in the range the depth of the pipeline will be determined by the average temperature of its deep layer (2 ^o C) and the surface layer (for example, 26 ^o C), which will average 12 ^o C. These temperature indicators (12 and 2 ^o C) will determine the difference in the levels of the surface water layer and water level in the tank and pipeline.

At the same time, different values of the density of water in the tank and the surface layer will be determined by the temperature in the surface layer (26 ^o C) and in the tank (2 ^o C).

Based on the fact that the water levels in communicating vessels (in this case, in the pipeline and tank relative to the surrounding water) depend on its density in these vessels, and the density is inversely dependent on temperature, it follows that the high density of water in the tank compared with the surface layer at a temperature difference of 24 ^o C will ensure the outflow of water from the tank, since differences in water temperatures, which determine their different densities in the tank (2 ^o C) and the surface layer (26 ^o C), are significantly larger compared to the differences in middle the temperature of the surrounding water (12 ^o C) and the temperature of the water in the tank (2 ^o C), which determine the different levels of ambient water and water in the tank.

 Or, in other words, the temperature and hydromechanical conditions of the system are such that the influence of different density of water on the creation of its flow from the tank is more significant compared to the difference in its levels in the surrounding water body and tank.

 The movement of atmospheric air through the duct 6 from the inlet 7 to the outlet 8 and the constant updating of the air in contact with the cooling partition 10 occurs without the expenditure of energy from the side naturally by cooling the air in the duct and increasing its density, which leads to to the expiration of cold and denser air from the outlet 8, which is located below the inlet 7. This movement of the cooled denser air is facilitated by the inclination of the partition to the side well outlet. Water vapor contained in the atmospheric air condenses on the upper cooled surface of the partition and the condensate formed flows down the inclined partition into the vessel 11 for collecting fresh water. On the non-condensable surface of the partition, water settles in the form of separate drops, which facilitates its movement along the inclined surface of the partition, and the absence of a film of water with low thermal conductivity on the partition surface increases the heat flux through the partition.

During operation of the described device, it is possible to cool the partition to about 2 ^° C, i.e. to the temperature of the water entering the pipeline from its deep layers. This provides the possibility of condensation of water vapor in almost any state of ambient air.

 The possible use, if necessary, of a pump and a fan increases the reliability of the described device even with a relatively small difference in water temperatures in the surface and deep layers of the reservoir.

Due to the constant and inexhaustible temperature difference shown above in the surface layer of sea water T ₂ and its deep layers (T ₁ ), the operation of the described device occurs almost in the mode of a perpetual motion machine, i.e. constantly, continuously, automatically, without any control or other intervention, without spending fuel and energy resources and other material resources, without environmental pollution, practically without wear and tear, and with a minimum number of maintenance (monitoring) personnel.

Claims (6)

 1. A device for producing fresh water, using the cold of the deep layers of water and containing a heat exchange surface on which moisture condenses from the outside air, and the condensate that has collected is collected in a condensate collection vessel, characterized in that the device contains heat water isolated in the surface layer and a container communicating with ambient air filled with running cold water entering through a pipe connected to the container, which is lowered into the deep cold layers of water when in relation to the surrounding water, it is a communicating vessel, the upper part of which is located above the level of the surface water layer of the reservoir and freely communicates with the surrounding air, a bottom hole is made in the lower part of the tank through which free flow of more dense cold water from the tank to the limits the surrounding surface layer of warmer and less dense water and this creates a continuous stream of cold water through the pipeline and capacity from the deep layers of the reservoir to the surface layer and in this stream, within the capacity of the tank, a heat exchange surface is installed in the form of a partition separating the condensation zone and the cooling zone, one surface of the partition facing down to the cooling zone is washed with cold running water, and the other surface facing up to the condensation zone can communicate with the surrounding air with the possibility of condensation of the water vapor contained therein and is connected to a vessel for collecting water condensate obtained from the ambient air.  2. The device according to claim 1, characterized in that the surface of the partition facing up towards the condensation zone has a non-wettable coating.  3. The device according to claim 1, characterized in that the partition is made in the form of the bottom wall of the duct freely open on both sides and the surface of the partition facing down into the cooling zone is washed with cold water flowing through the tank, while the inlet of the duct is facing away from the pipeline and placed above the outlet of the duct facing the pipeline, which provides air movement through the duct from the inlet to the outlet by cooling the air and increasing its density and when moving along the cooled surface of the partition.  4. The device according to claim 1, characterized in that the partition is placed in the tank with an inclination towards the vessel for collecting water condensate, which is installed at the edge of the partition, facing the pipeline.  5. The device according to claim 1, characterized in that an axial vane pump is additionally installed in the water stream through the pipeline and the tank, which provides increased reliability and an increase in the speed of movement of water in this stream.  6. The device according to claim 1, characterized in that an axial fan is additionally installed within the duct, providing increased reliability of the creation of air flow and an increase in the mass of air passing over the partition per unit time.