RU2184592C2 - Method of fresh water production and desalter for its embodiment - Google Patents

Abstract

FIELD: methods and desalters for production of fresh water from sea and mineralized waters and industrial waste water. SUBSTANCE: method includes supply of preliminarily heated saline water to evaporation chamber, its evaporation, condensation and collection for user. Additionally performed parallel supply of fresh water to condensation chamber where it is used for catching and condensation of saline water steam and separation of excessive amount of fresh water for user. In so doing, supply of saline and fresh waters to evaporation chamber is carried out in two stages including rarefaction and pressing. Volume of supply of fresh water exceeds that of supply of saline water. Temperature of saline water, in this case, exceeds temperature of cold water at least by 18 C. Desalter has an evaporation chamber, condensation chamber and system of pipelines with valves for supply and discharge of saline and fresh water, fresh water tank with system of its cooling and supply to condensation chamber, and body whose bottom and cover accommodate partitions separating saline and fresh waters. Located between body and cover are panels with holes or injectors through which saline and fresh waters in the form of drops run off into evaporation and condensation chambers separated by a separator. Located inside condensation chamber are vacuum header connected with a vacuum pump via shutoff valve, and also cooler, reservoir for heating of saline water and tank accumulating saline water. Desalter is also provided with indicators of levels of filling the evaporation chamber, condensation chamber and tanks of fresh water. System of pipelines with valves for supply and discharge of saline and fresh waters includes pump valves, flow meters and filters. EFFECT: reduced energy consumption per unit of volume of product - fresh water due to simple method and desalter reliable in operation and simple servicing of desalter and process. 14 cl

Description

 The invention relates to a device for desalination of water and can be used for the production of fresh water from sea and saline waters and industrial effluents.

 A known method of producing fresh water, described in the operation of the desalination device in the copyright certificate 1669468, published 15.08.91. Bull. 30, including the supply of salt water with preheating to a certain temperature in the chamber, bring it to volumetric boiling and the resulting steam is condensed in the collector, and then collected and discharged to the consumer. This method involves a difficult to manufacture installation, which will be energy-intensive and require significant operating costs.

 Known desalination of sea water, containing a pump for the extraction of sea water, a block of chambers with condensers, dehumidifiers, mixers and heat exchangers, to which hot air and sea water are supplied by a compressor through a heater, and a water supply system with shut-off and non-return valves. See, for example, the description of the copyright certificate 1669468, published 08/15/91. Bull. 30. This desalination plant is difficult to manufacture, energy intensive, and requires significant operating costs.

 A known method of producing fresh water, taken as a prototype and described in the desalination device of the patent of the Russian Federation 2013315, published on 05/30/94. Bull. 10, including the supply of salt water with preheating in a heat exchanger, then in condensers, additional heat exchangers and, finally, in the mixing chambers of the spray guns, where it is sprayed in the chambers under reduced pressure and the resulting water vapor condenses from the bottom of the trays of colder sea water and flows into the trays for fresh water, located below, and then to the consumer. This method involves a difficult to manufacture installation, which will be energy-intensive and require significant operating costs.

 The closest technical solution adopted for the prototype is a desalination plant containing a seawater extraction pump, a heater, a separation chamber, a refrigerator and a piping system with pumps for the extraction of brine and water, see the description of RF patent 2013315, published on 05/30/94, Bull. 10.

 Although compared to the analogue, this desalination plant is simpler and more economical to manufacture, its operation involves planned stops for preventive maintenance of the rotation mode. And performance directly depends on the size of the installation. At the same time, an increase in the size of the installation leads to an increase in energy costs, and ultimately, costs per unit volume of fresh water produced increase.

 The task to which the group of inventions is directed is to obtain a distillate using a simpler method and a reliable device. The expected technical result is to reduce energy consumption per unit volume of products - fresh water, simplification of service.

To this end, in a method comprising supplying pre-heated salt water to the evaporation chamber, its evaporation, condensation and collection to the consumer, additionally, parallel supply of fresh water to the condensation chamber is performed, where it captures and condensates the salt water vapor and selects excess fresh water to the consumer, In this case, the supply of salt and fresh water to the evaporation chamber is carried out in two stages, including vacuum and pressure, and the supply of fresh water exceeds the supply of salt water, while the temperature of the salt dy exceeds the temperature of cold water by at least 18 ^o C.

 For this, the desalination device comprising an evaporation chamber, a condensation chamber and a piping system with fittings for supplying and discharging salt and fresh water additionally includes: a fresh water tank with a cooling system and supplying it to the condensation chamber and the housing, in which the partitions are located in the bottom and cover, separating salt and fresh water, and between the body and the cover there are panels with openings or nozzles through which salt and fresh water, respectively, flow in the form of droplets into the chambers of evaporation and condensation, p Thousands separator separator, and condensation is within a vacuum manifold coupled to a vacuum pump chamber through the check valve and cooler salt water pool heating storage tank of saltwater. The desalination plant is equipped with level indicators for the evaporation chamber, condensation chamber, and fresh water tanks. A piping system with fittings for supplying and discharging salt and fresh water includes pumps, valves, flow meters and filters.

 The drawing shows a diagram of a desalination plant.

In practice, the implementation of the proposed method is as follows. From a source of salt water, which may be, for example, sea, ocean, lake, it is selected and heated by solar heat to a temperature of 40-45 ^o C. Then, heated salt water is supplied to the evaporation chamber in the form of falling drops. At the same time, they take a certain amount of fresh water, cool it to a temperature of 18 ^o C and feed it into the condensation chamber in the form of falling drops. Streams of drops of salt and fresh water fall parallel to each other in a closed limited space of the housing 1. Simultaneously with the supply of salt and fresh water, the chamber is evacuated so that the heated salt water begins to evaporate and the resulting vapor passes through the drops of falling fresh water and settles on them, creating her surplus. Then the excess is collected in an additional container to the consumer.

 The desalination unit consists of a housing 1 and a cover 2. The lid and bottom of the desalination unit are divided into salt water compartments 3 and fresh water compartments 4 by partitions 5 and 6. The casing has evaporation chambers 7, condensation chambers 8, separators 9, salt water level indicators 10 and fresh 11 vacuum manifolds 12 for creating and maintaining the necessary rarefaction and suction of air and dissolved gases by means of a vacuum pump 13 through valve 14. The cover 2 in the lower part has panels 15 and 16 with openings or nozzles through which, respectively, salt and fresh water flows in the form of droplets into evaporative 7 and condensation 8. The desalination plant has systems for supplying and draining salt and fresh water. The fresh water supply system includes a tank 17 with a level gauge 18 pump 19, a flow meter 20 valves 21 and 22. The fresh water drain system includes a storage tank 23 with a level gauge 24 and a valve 25 through which the distillate enters the mineralizer and disinfectant (not shown) and then to the consumer. Fresh water is drained from the desalination unit through a valve 26 to a tank 17 and through a valve 27 to a storage tank 23. The tank 17 has a cooler 28. The salt water supply system includes a pump 29 with a filter 30, valve 31, and a swimming pool 32 for heating salt water with solar heat, pump 33 and storage tank 34, filter 35, pump 36 with flow meter 37 and valves 38, 39 for regulating the pressure. The system for draining salt water from the desalination plant is made through valves 40 and 41.

Desalination works as follows. The valve 31 is preliminarily opened and with the pump 29 through the filter 30 the pool 32 is filled with salt water, where it is heated with solar heat to a temperature of 40-45 ^o C, and then with the pump 33 it is pumped to the salt water storage tank 34, which provides desalination operation at night, when there is no sun. At the same time, through the valve 42, from the external source, the tank 17 is filled with fresh water, in which the water is cooled with a cooler 28 to a temperature of 16-18 ^o C. The filling of the tank is controlled by the level gauge 18. After filling the pool 32 and tanks 34 and 17, the valve opens 14 and the vacuum pump 13 is turned on, with the help of which a vacuum of 5-7 m water column is created in the desalination unit. After that, valves 39, 38 on the supply line and 40, 41 on the salt water discharge line open. At the same time, valves 21 and 22 on the supply line and 26 on the line for draining fresh water from the desalination unit 1 are opened. The pump 36 is turned on, and the heated salt water is supplied to the compartments 3 of the lid 2 of the desalination plant and through the holes in the panels 15 or nozzles (their specific designs are not shown in the drawing) enters into the evaporation chambers in the form of droplets 7. Salt water flow is controlled and regulated using flow meter 37 and valves 38, 39, 40 and 41. Once in the desalination unit bottom compartments, the salt water then flows through the salt water drain pipelines to the salt water source (sea or lake) and partially to the pool 32 for re-supply to the desalination plant. Simultaneously with the pump 36, the pump 19 is turned on, and cold fresh water is supplied to the compartments 4 of the cover 2 of the desalination plant and flows through the holes in the panels 16 or nozzles (their specific designs are not shown in the drawing) in the form of droplets into the condensation chambers 8. Fresh water consumption control and regulation water is carried out using a flow meter 20 and valves 21, 22 and 26. Once in the desalination unit bottom compartments, the heated fresh water is then returned to the tank 17 through fresh water discharge pipelines, where it is cooled and again fed into the compartments 4 of the lid 2. Excess fresh water s, which are formed by condensation of the vapors through the valve 27 into the storage tank 23. The heated salt water, falling as droplets into the evaporation cavity 7 sparse cameras intensively evaporates. The resulting vapor will tend to fall into the zone of reduced pressure, i.e. towards the vacuum manifolds 12. Passing through the separators 9, which are cooled with cold water from the compartments 4, the steam is partially cooled on them and flows down with drops. The bulk of the steam falls under the cold drops of fresh water, condenses on them and also flows down to the bottom of the housing 1, and then into the tank 17. Thus, the fresh water passing through a closed circuit, condensing the salt water vapor on itself, is heated. Therefore, so that the condensation process does not interrupt, fresh water entering the tank 17 is cooled before being fed into the condensation chambers. To ensure the design capacity of the desalination plant, the difference between the temperature of the incoming salt water and the cooled fresh water should be at least 18 ^o C. To maintain the temperature difference, partitions 5 and 6 serve simultaneously as thermal bridges, preventing heat exchange between hot and cold water. Subsequently, under the established mode, the vacuum is constantly provided by a column of water, which is formed in the pipelines of salt and fresh water, and in the bottom of the desalination unit at a level of 5-7 meters, but below the partitions 7. For this purpose, the case is installed on special supports (in the drawing they are not shown), the height of which is determined depending on the height above sea level in the area where it is operated.

 Thus, the method of producing fresh water and the design of the desalination plant make it possible to use fresh water reversed in a closed circuit as a condenser. The installation can operate automatically and be serviced by one or two operators. It is designed to work in the southern regions, where solar energy can be used to heat salt water, and underground natural sources circulating in a closed circuit to cool fresh water. This makes it possible, in contrast to tubular and other designs, to reduce the temperature head (differential) between the deposited steam and the refrigerant and increase the efficiency of the desalination plant. The desalination unit can be made in a rectangular or cylindrical (coaxial) shape. In addition, to increase productivity and reduce energy consumption, it is possible to build a desalination plant in the form of modules connected in blocks. The proposed desalination plant requires a minimum of maintenance since it can work in automatic mode.

Such a method and a desalination plant with a chamber volume of 50 m ³ and a flow rate of salt and fresh water of 87.5 l / s make it possible to provide a fresh water output of 0.6-1.2 l / s to the consumer.

Claims (14)

 1. A method of producing fresh water, including the supply of pre-heated salt water to the evaporation chamber, its evaporation, condensation and collection to the consumer, characterized in that simultaneously with the supply of pre-heated salt water, a cooled fresh water is supplied to the condensation chamber in parallel and captured by it and condensation of salt water vapors and the selection of excess fresh water to the consumer, while the supply of salt and fresh water is carried out by means of rarefaction and pressure, in which the volume of fresh water The ode exceeds the supply of salt water. 2. The method according to p. 1, characterized in that the temperature of salt water exceeds the temperature of cold water by at least 18 ^o C.  3. The method according to p. 1, characterized in that the supply volume of fresh water exceeds the supply volume of salt water twice.  4. The method according to p. 1, characterized in that the preheating of salt water is done by solar heat.  5. The method according to p. 1, characterized in that the selection of excess fresh water to the consumer is carried out through an additional fresh water tank.  6. The method according to p. 1, characterized in that the cooling of fresh water is produced by underground natural sources.  7. The method according to p. 1, characterized in that the vacuum is created within 5-7 m of water column.  8. The method according to p. 1, characterized in that the drained salt water partially enters the pool for re-supply to the desalination plant.  9. Desalination plant, consisting of a housing with evaporation and condensation chambers, a salt and fresh water supply and discharge system, characterized in that it further comprises a salt water heating pool and a salt water storage tank, a fresh water tank with a cooling and supply system a condensation chamber, inside which a vacuum manifold is located, connected to the vacuum pump through a shut-off valve, partitions are installed in the bottom and cover of the housing separating salt and fresh water, panels with holes are placed between the housing and the cover, h Through which, respectively, salt and fresh water flows in the form of droplets into the evaporation and condensation chambers, separated by separators, the body itself is placed on supports of a certain height, the system for supplying and draining salt and fresh water includes pumps, valves, flow meters and filters.  10. Desalination plant according to claim 9, characterized in that the partitions separating salt and fresh water and located in the bottom and lid of the housing are made in the form of thermal bridges.  11. Desalination plant according to claim 9, characterized in that the holes in the panels are made in the form of nozzles.  12. Desalination plant according to claim 9, characterized in that it is equipped with level indicators for filling the evaporation chamber, condensation chamber and fresh water tanks.  13. Desalination plant according to claim 9, characterized in that the height of the supports is determined by the height of its placement above sea level.  14. Desalination plant according to claim 9, characterized in that the casing can be made rectangular or cylindrical coaxial.