RU2770360C1 - Sea water desalination method - Google Patents

Abstract

FIELD: pumps; technological processes.SUBSTANCE: invention can be used for agricultural, industrial and domestic water supply. In the method of sea water desalination, low hydrostatic pressure of the water column in the water area is used. To achieve the pressure required during desalination of sea water, a positive displacement pump with reciprocating movement of working member 4 is used, provided by using the energy of sea waves, taken during the reciprocating movement of buoy 2 with positive buoyancy, attached to pump housing 3, and elastic membrane 6, from the lower side attached to tightening weight 9 at the sea bottom, and from the upper side rigidly connected to working member 4. Pressure in the pump is increased due to the difference in the areas of elastic membrane 6 and the cross section of working member 4. Inside housing 3 to prevent leakage of sea water there is flexible sealed hose 5 connected to it. To reduce friction between flexible sealed hose 5 and working member 4, grease is used. Reverse osmosis module 1 is placed inside buoy 2, the weight of which and its displacement are selected so that when it moves upwards on the wave crest, the force of hydrostatic water pressure acting on elastic membrane 6 is overcome. Weight of tightening weight 9 at sea bottom is selected so that it is more than buoyant force acting on buoy 2.EFFECT: reduced power consumption due to use of renewable energy of sea waves, continuous operation during a day.1 cl, 1 dwg

Description

The invention relates to seawater desalination using reverse osmosis technology and can be applied to agricultural, industrial and domestic water supply.

A known method of desalination of sea water, including the evaporation and condensation of water vapor using a device for its implementation, which contains heat exchangers, water recycling systems, a heat pump, a vacuum chamber, rotating curvilinear channels located in it (patent RU 2359917 C1, C02F 1/04, published on 27.06.2009). The disadvantages of this method are the complexity of the design and the need for its implementation of large capital and operating costs.

The closest technical solution to the claimed method in terms of the totality of features is a method for producing low-salinity water, which consists in performing underwater water intake, installing a desalination plant with a reverse osmosis module, through which desalinated water is obtained using hydrostatic pressure (patent RU2223919 C1, C02F 1/00.1 /44, B01D 61/00, published 02.20.2004). The disadvantage of this method of water desalination is that in order to create hydrostatic pressure in front of the reverse osmosis module, sufficient to desalinate sea water, the reverse osmosis module must be immersed under the level of the water area to a depth of up to 250 meters, and in some water areas with high salinity of the sea and more than 250 m. This leads to an increase in capital and operating costs during its implementation.

The technical task of the invention is to create a simple method of seawater desalination using low hydrostatic pressure of the water column of the water area and renewable energy of sea waves to obtain water with low salinity, which reduces capital and operating costs, as well as the cost of obtaining fresh water.

The technical result of the claimed invention is the reduction of energy costs in the implementation of the method through the use of renewable energy of sea waves and the reduction of capital and operating costs due to the lower depth of placement of desalination modules in the sea.

According to the invention, the technical problem is solved, and the technical result is achieved as follows. The sea water desalination method includes the use of reverse osmosis modules and the hydrostatic pressure of the water column in the water area to produce water with reduced salinity. To obtain desalinated water and brine, a reduced hydrostatic pressure of the water column in the water area is used, which makes it possible to place reverse osmosis modules at a shallower depth in the water area. To achieve the required pressure sufficient for water desalination, positive displacement pumps with reciprocating motion of working bodies are used. The movement of the working bodies of the pumps is carried out using the energy of sea waves, removed during the reciprocating motion of buoys with positive buoyancy, fastened to the pump casings, and elastic membranes, fastened to bottom weights from the bottom side, rigidly connected to the working movable bodies of the pumps from the upper side. To reduce the weight of bottom weights, it is possible to use dynamic brakes fastened to the lower sides of the membranes and representing horizontal disks of a large area that provide hydraulic resistance during their vertical movements. The pressure in the pumps is increased due to the difference in the areas of elastic membranes in contact with sea water at the depth of their placement and the cross section of the moving working bodies of the pumps. Inside the pump casings, to prevent leakage of sea water from them, there are flexible sealed sleeves connected to the pump casings. Inside the sleeves, the reciprocating movement of the working bodies of the pumps is carried out due to the hydrostatic pressure of the water column and the energy of sea waves. To reduce friction between sealed flexible hoses and moving working parts of high pressure pumps, grease is used. Recovery of residual energy of the brine is carried out using hydro turbines and electric generators.

Figure 1 is a diagram of seawater desalination. The figure shows the following positions:

1 - reverse osmosis desalination module;

2 - buoy with positive buoyancy;

3 - volumetric pump housing;

4 - working movable body of the pump;

5 - sealed flexible sleeve;

6 - elastic membrane;

7 - air space above the membrane,

8 - pipeline communicating with the air atmosphere;

9 - weight on the bottom of the sea;

10 - filter for cleaning the intake sea water;

11 - suction check valve of the pump;

12 - discharge check valve of the pump;

13 - pipeline for supplying sea water with high pressure to the reverse osmosis module;

14 - pipeline for the removal of desalinated water;

15 - pipeline for removing brine from the reverse osmosis module;

16 - hydro-pneumatic accumulator to prevent pressure pulsations and flow rate of the discharged brine;

17 - hydraulic turbine for recuperation of the residual energy of the brine;

18 - electric generator;

19 - removal of waste brine.

The method of desalination of sea water (see figure 1) is implemented as follows.

Desalination modules (1) are placed inside buoys with positive buoyancy (2). At an insignificant depth in the sea area (about 10 meters), volumetric pumps (3) with reciprocating movement of working bodies (4) are placed in sealed flexible hoses (5) placed in pump housings (3) and hermetically connected to them. The working bodies of the pumps (4) are rigidly connected by elastic membranes (6). On the lower side, the membrane (6) communicates with the surrounding sea water at the depth of its installation; on the upper side, the membrane (6) communicates with the air atmosphere. The air space (7) between the membranes (6) and flexible hoses (5) is connected to the air atmosphere by a pipeline (8). Elastic membranes (6) are fastened with weights on the sea bottom (9). Pump housings (3) are connected to buoys (2) floating on the surface of the sea. Sea water is taken into the pump housings (3) through filters (10) and suction check valves (11). Sea water under pressure is supplied from pumps through discharge check valves (12) through pipelines (13) to reverse osmosis modules (1). Desalinated water is removed through pipelines (14), and brine is sent through pipelines (15) for the recovery of its residual energy to hydro-pneumatic accumulators (16), then to hydro turbines (17) connected to electric generators (18). The spent brine after the hydraulic turbines (17) is discharged through pipelines (19). Grease is used to reduce friction between sealed flexible hoses (5) and moving working parts of high pressure pumps (4). When the sea is rough, the buoy (1) reciprocates up and down. When the buoys (1) move upwards with positive buoyancy, sea water is sucked into the pump housings (3). When the buoys (1) move down, sea water is injected due to the hydrostatic pressure of water when the elastic membranes (6) and the working bodies of the pumps (4) move upwards. The weight of the buoys (2) with desalination modules (1) and the displacement of the buoys (2) are chosen so that when the buoys move up to the wave crest, the hydrostatic water pressure force acting on the elastic membranes (6) from below at the depth of their installation is overcome. The weight of bottom weights (9) without the use of dynamic brakes, which are flat horizontal disks of a large area connected to membranes (6) from below, and creating hydraulic resistance during their vertical movements, should be greater than the buoyancy force acting on the buoys (2). This is necessary to overcome the force of the hydrostatic pressure of sea water on the membranes (6) and ensure the process of suction of sea water into the pumps (3).

As an example, consider the implementation of the method when placing an elastic membrane with a diameter of 0.8 meters at a depth of 7 meters, where the excess hydrostatic pressure of sea water is about 0.7 atmospheres. The diameter of the cross section of the moving working body of the pump is 0.08 meters. We will take the height of the sea wave at a very weak wind equal to 0.4 meters with a period of 5 seconds. Under these conditions, the excess pressure of sea water in front of the reverse osmosis module will be 70 atmospheres, which is quite enough for its normal operation. The stroke of the working body of the pump in a sealed sleeve that displaces sea water into the reverse osmosis module is equal to the amplitude of the sea wave and is 0.2 meters. With continuous operation during the day, the pump can pump 17.3 cubic meters of sea water through the reverse osmosis module. Assuming that approximately half of the pumped water is used to form brine, the desalination plant's capacity for water with reduced salinity will be approximately 8.65 cubic meters per day.

The claimed technical solution makes it possible to use free renewable energy of the sea wave for water desalination and to install reverse osmosis modules at a much shallower depth in the sea, which makes it possible to reduce capital and operating costs for obtaining water with low salinity.

Claims (1)

A method for seawater desalination, including the use of a reverse osmosis module and the hydrostatic pressure of the water column in the water area, characterized in that a reduced hydrostatic pressure of the water column in the water area is used, to achieve the pressure required for seawater desalination, a positive displacement pump with a reciprocating movement of the working body, provided by using the energy of sea waves, removed during the reciprocating motion of a buoy with positive buoyancy, fastened to the pump housing, and an elastic membrane, fastened on the lower side with a load on the sea bottom, and on the upper side rigidly connected to the working body of the pump , the pressure in the pump is increased due to the difference in the areas of the elastic membrane and the cross section of the working body of the pump, inside the pump housing, to prevent leakage of sea water, a flexible sealed hose is placed, connected to the pump housing, to reduce friction between the flexible sealed the sleeve and the working body use grease, while the reverse osmosis module is placed inside the buoy, the weight of which and its displacement are chosen in such a way that when it moves up to the crest of the wave, the force of hydrostatic water pressure acting on the elastic membrane is overcome, and the weight of the weight on the seabed choose so that it is greater than the buoyant force acting on the buoy.

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