RU2359917C1 - Method of sea water desalination by utilising low-potential heat - Google Patents

Abstract

FIELD: treatment facilities.

SUBSTANCE: invention relates to water treatment, particularly to salt water desalination, for example sea water or mineralised water by distillation. The invention may be used for local fresh water supply. The method of sea water desalination provides for supplying water into curvilinear channel, where sea water flow excursed to the speed level whereat static pressure in the sea water flow falls below salt water boiling pressure at a given temperature of salt water. Gas-escape channel is provided in the curvilinear channel above the sea water flow surface to discharge saltwater vapour produced as a result of excursed sea water boiling in curvilinear channel. The salt water vapour from gas-escape channel is pumped and condensed. So, initially, seawater is taken from the environment and it flows through the heat-exchanger of circulation water system in condensing power plant, where it is heated. After that seawater is supplied to heat pump and separated into two flows. One heated seawater flow subject to desalination is directed to heat absorber of the heat pump where seawater is additionally heated up. The other seawater flow is directed to heat transfer unit where it is cooled down the ambient temperature and returned to the environment. At the same time, the seawater heated in heat absorber is supplied to curvilinear channel and additional curvilinear channel. Both curvilinear channels are placed in vacuum chamber. The salt water flow heated in heat absorber is excursed in curvilinear channels producing reactive jet at each curvilinear channel outlet to drive curvilinear channels around their common axis of rotation. Vapour from vacuum chamber is pumped to condensate tank via heat-exchanger-cooler.

EFFECT: reduced power inputs per one unit of fresh water volume produced.

4 cl, 1 dwg

Description

The invention relates to the field of water treatment, in particular to desalination of salt water, for example sea or saline water, by distillation, and can be used for local fresh water supply.

There is a known method of desalination, namely, that the initial salt water is supplied to the evaporator by a pump through a heater, a part of the steam generated in the evaporator, called secondary steam, is sent to the condenser, where it gives off heat to the circulating water and turns into distillate, and the other part of the secondary steam is directed into the heater, where it condenses and heats the initial salt water, while the resulting distillate and steam are then fed to the condenser, part of one stripped off water (brine) is drained and freshly added continuously w salt water (see. Astrata IA Desalination and deaeration of water on ships, Leningrad, State Publishing union ship industry 1966 s.41-42).

This method is quite productive with small dimensions and relatively small weight of the installation used, however, energy-intensive, which narrows the scope of its use.

A known method of producing fresh water, comprising supplying pre-heated salt water in a heat exchanger to a cylindrical chamber, where it acquires a rotational movement and due to the resulting pressure and velocity gradients, there is a volume boiling effect, the generated steam through the hole and nozzle is fed into a turbine playing the role of a condensate chamber, where the steam gives its energy to rotor rotation and condenses in the collector, covering the turbine, the resulting fresh water is removed by the pump, passes through refrigerators to and fed to the consumer, and the brine is removed from the cylindrical chamber by another pump (see patent RU No. 2013315, CL B63J 1/00, 05/30/1994).

This method of desalination allows you to get fresh water and uses steam energy. However, this method involves a difficult installation to manufacture, which will require significant operational and energy costs.

The closest to the invention in technical essence and the achieved result is a method of desalination of sea water, which consists in the fact that sea water is fed into a curved channel with acceleration in the latter stream of sea water to a speed at which the static pressure in the stream of sea water drops below the pressure corresponding to boiling at a given temperature of salt water, while in the curved channel above the surface of the flow of seawater, a gas outlet channel is formed to withdraw salt water vapor from the curved channel, about azovavshegosya at reflux dispersed seawater flow in a curved channel, wherein the resulting salt water vapor from the gas outlet duct is evacuated and is condensed (see. US № Patent 3509932, cl. B01D 1/16, 05.05.1970).

This method allows you to get fresh water from sea water at lower energy costs, however, it does not allow the full use of the kinetic energy of the flow of sea water, which reduces its effectiveness and, thereby, narrows the scope of its use.

The problem to which the present invention is directed, is a more complete use of the temperature of the stream of salt water during the process of obtaining fresh water.

The expected technical result is to reduce energy consumption per unit volume of the resulting product - fresh water.

This problem is solved, and the technical result is achieved due to the fact that the method of desalination of sea water by utilizing low-grade heat is that sea water is fed into a curved channel with acceleration in the latter stream of sea water to a speed at which the static pressure in the stream of sea water drops below the boiling pressure of salt water at a given temperature, while in the curvilinear channel above the surface of the flow of seawater a gas outlet channel is formed to withdraw salt vapor from the curvilinear channel water generated during the boiling of an accelerated stream of sea water in a curved channel, and the resulting salt water vapor from the gas outlet channel is pumped out and condensed, while first the sea water is taken from the environment and passed through a heat exchanger of the condensate power plant’s recycling water system, where the sea water is heated, after which sea water is fed into the heat pump, and the stream of sea water is divided into two streams, one stream of heated sea water intended for desalination, into They are poured into the heat pump heat sink, where the sea water is additionally heated, and the other excess part of the sea water is sent to the heat sink, where sea water is cooled to ambient water temperature and the cooled sea water is returned to the environment, sea water heated in the heat receiver is fed simultaneously to a curvilinear channel and in at least one additional curvilinear channel, the curvilinear channels are located in a vacuum chamber, are combined from the side of the inlet of salt water heated in the heat receiver ke, and perform with the possibility of free rotation and diverging in different directions from the common axis of rotation, while in the curved channels the stream of salt water heated in the heat sink is accelerated with the formation of a jet stream at the outlet of each curved channel to drive the curved channels around the common axis of rotation and forming due to the indicated rotation of the curved channels swirling around the longitudinal axis of each curved channel of the salt water flow with the formation along the axis of each curved of the gas channel of the exhaust channel, in a vacuum chamber maintain a pressure below the pressure at which salt water heated in the heat sink boils at its given temperature, steam heated in the heat sink of salt water from the vacuum chamber is pumped out through a heat exchanger-cooler, in which it is cooled to a temperature below the condensation temperature steam of salt water heated in the heat sink to a condensate collecting tank of salt water - distillate, in which the vacuum pump maintains the pressure below atmospheric pressure, but yshe pressure at which a distillate boiling possible and at least accumulation is removed from the vacuum chamber formed therein a brine of salt water, and from the tank for collecting vapor condensate salt water - distillate salt water (fresh water).

Curved channels are mounted on a common shaft of rotation to drive into rotation from the last consumer of energy of rotation of the shaft, for example an electric generator or pump installation.

Part of the flow of seawater heated in the heat exchanger is passed through a heat exchanger-cooler before being fed to the heat exchanger, where this part of the flow of seawater heated in the heat exchanger is heated by the heat of the condensed steam heated in the seawater heat exchanger, after which this part of the flow of seawater heated in the heat exchanger is connected to the direct flow into the heat sink heated in the heat exchanger seawater.

Part of the flow of seawater heated in a heat exchanger is heated in a heat exchanger located in a brine of seawater before being fed to a heat exchanger-cooler.

As the analysis of the operation of various types of desalination plants has shown, it is possible to combine the process of desalination of sea water with the process of converting the kinetic energy of the flow of sea water into mechanical energy of rotation of the shaft while intensifying the process of boiling sea water without first preheating the sea water.

The supply of sea water to several curved channels diverging in different directions, combined from the input side, connected to the same source of salt water, and the execution of curved channels, for example, in a disk mounted with the possibility of free rotation on the shaft, can essentially create a turbine, the curvilinear channels of which the process of intense boiling of sea water is organized due to the acceleration of the flow of sea water in curvilinear channels, usually tapering along the flow of salt water. The acceleration of the salt water flow in curved channels allows you to reduce the static pressure in the water flow and, as a result, lower the temperature at which salt water boils, which eliminates the need for pre-heating salt water. Expiring from curved channels, the stream of salt water causes the rotation of the curved channels together with a shaft to which a disk is attached, in which the channels are made and whose axis is a common axis around which the curved channels rotate. The rotation of the curved channels in combination with the longitudinal movement of the stream of salt water along the curved channels causes the rotation of the stream of salt water around the longitudinal axis of the curved channels. As a result, the flow of salt water is distributed along the wall of the curved channels with the formation of gas outlet channels inside the curved channels, which allows the steam to be boiled away with salt water with minimal hydraulic resistance. The location of the curved channels in the vacuum chamber and the pumping out of the last steam through the heat exchanger-refrigerator into the salt water steam condensate collecting tank prevents the salt water steam condensation process after it leaves the curved channels and the steam supply to the salt water steam condensate collecting tank using one a vacuum pump connected to a tank for collecting condensate of salt water vapor, which simplifies the design of the desalination plant, reduces the energy consumption for producing distillate with enoy water and increases reliability.

Additional opportunities to reduce energy costs for desalination of sea water and at the same time to improve the environmental situation around the condensation power plant are achieved due to the fact that first, sea water is taken from the environment and passed through a heat exchanger of the circulating water system of the condensation power plant, where sea water is heated, and then sea water water is supplied to a heat pump, and the seawater stream is divided into two streams, one stream of heated seawater, designed to determine neniya is directed to the heat sink of the heat pump, where sea water is further heated, and the other unnecessary portion of the seawater is directed into teplootdatchik where sea water is cooled to ambient temperature and the cooled sea water is returned to the environment. As a result, salt water arrives at a higher temperature and at the same time sea water is discharged into the environment at the same temperature at which it was taken from the environment, which is important when operating offshore power plants. At the same time, the environment is not damaged.

The drawing schematically shows a desalination plant for implementing the method of desalination of sea water.

The desalination plant includes a vacuum chamber 1, in which a turbine 3 with curved channels 4 connected on the input side and connected to the heated salt water supply pipe 5 passed through the hollow shaft 2 is mounted on the hollow shaft 2 with free rotation. In the lower part to the vacuum chamber 1 is connected a pipe 6 of the brine outlet. In the upper part, the vacuum chamber 1 through the bypass pipe 7 is connected to a heat exchanger-cooler 8 and through the latter to a tank 9 for collecting condensate of salt water vapor - salt water distillate (desalinated salt water), while the indicated tank 9 is simultaneously connected via a drain pipe 10 to vacuum pump 11. In the lower part, the tank 9 for collecting condensate of salt water vapor is provided with a pipe 12 for discharging salt water distillate. The vacuum chamber 1 is connected to a heat pump 14 communicated with the heat exchanger 13 of the condensing power plant water recycling system, while the heat exchanger 13 is in communication with both the heat receiver 15 and the heat pump 16 of the heat pump 14. The vacuum chamber 1 is equipped with a heat exchanger 17 for removing heat from the brine of sea water and heating this heat heated in the heat exchanger 12 of sea water.

The method of desalination of sea water by utilizing low-grade heat is implemented as follows.

First, seawater is taken from the environment and passed through a heat exchanger 13 of the condensate power plant’s recycling water system, where the seawater is heated. Then, the sea water is supplied to the heat pump 14, and the stream of sea water is divided into two streams, one stream of heated sea water intended for desalination is sent to the heat receiver 15 of the heat pump 14, where the sea water is additionally heated, and the other excess part of the sea water is sent to heat transfer device 16, where sea water is cooled to ambient water temperature and the cooled sea water is returned to the environment.

The sea water heated in the heat receiver 15 is simultaneously supplied to all curved channels 4, while in the curved channels 4 the stream of salt water heated in the heat receiver 15 is accelerated with the formation of a jet stream at the outlet of each curved channel 4, which leads to rotation of the turbine 3 and, accordingly, curved channels 4 around a common axis of rotation and formation due to the indicated rotation of curved channels 4 swirling around the longitudinal axis of each curved channel 4, a stream of salt water with formation along and each curved channel 4, gas outlet channel. In the vacuum chamber 1, the pressure is maintained below the pressure at which the salt water heated in the heat receiver 15 boils at its given temperature. The steam of salt water heated in the heat receiver 15 is evacuated from the vacuum chamber 1 through a cooler-heat exchanger 8, in which it is cooled to a temperature below the condensation temperature of the salt water heated in the heat receiver 15, into a container 9 for collecting condensate of salt water - distillate vapor, in which the pump 11 maintain a pressure below atmospheric pressure, but above the pressure at which boiling of the distillate is possible. The vacuum pump 11 through the discharge pipe 10 pumps non-condensed salt water vapor and other gases that were dissolved in salt water, such as air, and released from the salt water during its boiling out of the tank 9. As it accumulates, salt water brine formed in it is discharged from the vacuum chamber 1 through a pipe 6, and salt water (fresh water) is distilled from a container 9 for collecting salt water vapor condensate through a pipe 12.

Since the curved channels 4 are installed on a common shaft of rotation, it is possible to use a turbine 3 to drive the rotational energy of the shaft into rotation, for example, an electric generator or a pump unit (in the drawing), which allows you to compensate for a part of the energy spent on obtaining salt water distillate.

Part of the flow of seawater heated in the heat exchanger 13 can be passed through the heat exchanger cooler 8 before being fed to the heat exchanger 15, where this part of the seawater heated in the heat exchanger 13 is heated by the heat of condensed seawater steam, after which this part of the seawater flow is connected directly to the direct into the heat sink 15 heated in the heat exchanger 13 with sea water.

Part of the flow of sea water heated in the heat exchanger 13 before being fed to the heat exchanger-cooler 8 can be heated in the heat exchanger 17 located in the brine of sea water.

The present invention can be used for desalination of sea water at various kinds of power plants located in the seas and oceans, for example, offshore platforms for mining from the seabed or in coastal marine power plants or at FNPPs (floating nuclear power plants).

Claims (4)

1. The method of desalination of sea water by utilizing low-grade heat, namely, that sea water is fed into a curved channel with acceleration in the latter stream of sea water to a speed at which the static pressure in the stream of sea water drops below the boiling pressure of salt water at a given salt temperature water, while in the curved channel above the surface of the flow of seawater, a gas outlet channel is formed to withdraw from the curved channel steam of salt water formed during the boiling of the dispersed flow of fruit juice water in a curvilinear channel, and the salt water formed from the gas outlet channel is pumped out and condensed, characterized in that first the sea water is taken from the environment and passed through a heat exchanger of the condensate power plant’s recycling water system, where the sea water is heated, after which the sea water is fed into heat pump, and the stream of sea water is divided into two streams, one stream of heated sea water intended for desalination is directed to the heat receiver of the heat pump, where the sea this water is additionally heated, and the other excess part of the sea water is sent to the heat sink, where the sea water is cooled to ambient water temperature and the cooled sea water is returned to the environment, sea water heated in the heat sink is fed simultaneously to a curved channel and, at least at least one additional curvilinear channel, the curvilinear channels are placed in a vacuum chamber, are combined from the side of the inlet of salt water heated in the heat receiver and are made to rotate freely and diverging in different directions from the common axis of rotation, while in the curved channels the stream of salt water heated in the heat sink is accelerated with the formation of a jet stream at the outlet of each curved channel to drive the curved channels around the common axis of rotation and form curved channels due to the indicated rotation a stream of salt water swirling around the longitudinal axis of each curvilinear channel with the formation of a gas outlet channel along the axis of each curvilinear channel in a vacuum chamber the pressure is kept below the pressure at which the salt water heated in the heat sink boils at its given temperature, the steam of salt water heated in the heat sink is pumped out of the vacuum chamber through a heat exchanger-cooler, in which it is cooled to a temperature below the condensation temperature of the steam of salt water heated in the heat sink, in a container for collecting condensate of salt water vapor - distillate, in which the vacuum pump maintains the pressure below atmospheric pressure, but above the pressure at which boiling disti is possible llata, and, as they accumulate, salt water brine formed in it is removed from the vacuum chamber, and salt water distillate (fresh water) is collected from the salt water vapor condensate collecting tank. 2. The method according to claim 1, characterized in that the curved channels are installed on a common shaft of rotation for driving into rotation from the last consumer of the energy of rotation of the shaft, for example an electric generator or pump installation. 3. The method according to claim 1, characterized in that a part of the flow of seawater heated in the heat exchanger is passed through a heat exchanger-cooler before being fed to the heat exchanger, where this part of the seawater heated in the heat exchanger is heated by condensed steam heat of seawater heated in the heat exchanger, after which this part of the flow of seawater heated in the heat exchanger is connected to the seawater heated in the heat exchanger directed directly to the heat sink. 4. The method according to claim 3, characterized in that a part of the stream of sea water heated in the heat exchanger is heated in a heat exchanger located in the brine of sea water before being fed to the heat exchanger-cooler.