Device for sea water desalination and power generation

Abstract

A device for sea water desalination and power generation, including: a tidal current turbine, a coupling, a revolving shaft, a booster pump, and a body. The body includes a chamber, a divider, and an end cover. The divider and the end cover are in fixed connection to the body, and the divider divides the chamber into a closed pumping chamber and a closed desalination and power generation chamber. The booster pump is disposed in the pumping chamber and is driven by the revolving shaft. The tidal current turbine is connected to the revolving shaft via the coupling. The desalination and power generation chamber includes a seawater pretreatment device, a seawater desalinating unit including an unsteady reverse osmosis membrane, a flow battery, and a controller. The booster pump is connected to the seawater pretreatment device via an inlet tube, and is connected to the seawater desalinating unit via an outlet tube.

Claims

1. A device for seawater desalination, comprising: a) a turbine; b) a coupling; c) a revolving shaft; d) a booster pump, the booster pump comprising an inlet channel and an outlet channel; e) a main body, the main body comprising a chamber, a divider, an end cover, a seawater inlet, a freshwater outlet, and a brine discharge outlet; f) a first shaft bearing; g) a second shaft bearing; h) a seawater desalinating unit comprising a reverse osmosis membrane; and i) a seawater pretreatment device; wherein: the chamber is enclosed by the end cover; the divider is disposed in the chamber, and the divider and the end cover are in fixed connection; the divider subdivides the chamber into a pumping chamber and a desalination and power generation chamber; the booster pump is disposed in the pumping chamber; the first shaft bearing is disposed on the divider; the second shaft bearing is disposed on an end of the end cover, wherein the end of the end cover is adjacent to the pumping chamber; the revolving shaft is supported by the first and second shaft bearings; one end of the revolving shaft is connected to the turbine via the coupling, and the other end of the revolving shaft is fixedly connected to the booster pump; the turbine is adapted to be driven by a tide current; the booster pump is adapted to be driven by the revolving shaft; the booster pump is connected to the seawater pretreatment device via the inlet channel, and is connected to the seawater desalinating unit via the outlet channel; the seawater pretreatment device and the seawater desalinating unit are disposed in the desalination and power generation chamber; and the booster pump is adapted to boost pressure of seawater that is fed to the reverse osmosis membrane.

2. A device for seawater desalination, comprising: a) a turbine; b) a coupling; c) a revolving shaft; d) a booster pump, the booster pump comprising an inlet channel, an outlet channel, a swash plate holder, a swash plate, a cylinder, a plurality of plunger chambers, a plurality of plungers, a plurality of reset springs, and a multi-channel valve plate; e) a main body, the main body comprising a chamber, a divider, an end cover, a seawater inlet, a freshwater outlet, and a brine discharge outlet; f) a first shaft bearing; g) a second shaft bearing; h) a seawater desalinating unit comprising a reverse osmosis membrane; and i) a seawater pretreatment device; wherein: the chamber is enclosed by the end cover; the divider is disposed in the chamber, and the divider and the end cover are in fixed connection; the divider subdivides the chamber into a pumping chamber and a desalination and power generation chamber; the booster pump is disposed in the pumping chamber; the first shaft bearing is disposed on the divider; the second shaft bearing is disposed on an end of the end cover, wherein the end of the end cover is adjacent to the pumping chamber; the revolving shaft is supported by the first and second shaft bearings; one end of the revolving shaft is connected to the turbine via the coupling, and the other end of the revolving shaft is fixedly connected to the booster pump; the turbine is adapted to be driven by a tide current; the booster pump is adapted to be driven by the revolving shaft; the booster pump is connected to the seawater pretreatment device via the inlet channel, and is connected to the seawater desalinating unit via the outlet channel; the seawater pretreatment device and the seawater desalinating unit are disposed in the desalination and power generation chamber; the booster pump is adapted to boost pressure of seawater that is fed to the reverse osmosis membrane; the booster pump employs a plunger-type rotary pump; the swash plate holder is disposed in the pumping chamber and is in fixed connection to the end cover; the swash plate is fixedly supported by the swash plate holder; the revolving shaft is in fixed connection to the cylinder; the plurality of plunger chambers is disposed in the cylinder, each of the plurality of plungers is disposed in one of the plurality of plunger chambers, and each of the plurality of springs is disposed in and supported by one of the plurality of plunger chambers; each of the plurality of plungers is supported by one of the plurality of springs, and is disposed between the one of the plurality of springs and the swash plate; the inlet channel and the outlet channel are disposed in the multi-channel valve plate; each of the plurality of plunger chambers is adapted to communicate with the inlet channel or the outlet channel; and when the cylinder is rotated, the swash plate is cooperated with each of the plurality of springs to move one of the plurality of plungers.

3. The device of claim 2, wherein a flow regulator is disposed in the pump chamber to regulate a slope angle of the swash plate with respect to the revolving shaft.

4. The device of claim 1, wherein when the revolving shaft is a horizontal shaft, the turbine is a horizontal shaft turbine; when the revolving shaft is a vertical shaft, the turbine is a vertical shaft turbine.

5. The device of claim 2, wherein when the revolving shaft is a horizontal shaft, the turbine is a horizontal shaft turbine; when the revolving shaft is a vertical shaft, the turbine is a vertical shaft turbine.

6. The device of claim 1, further comprising a flow battery disposed in the desalination and power generation chamber, wherein the seawater desalinating unit further comprises a brine tube, and the flow battery is connected to the brine tube and is adapted to convert chemical energy into electrical energy.

7. The device of claim 2, further comprising a flow battery disposed in the desalination and power generation chamber, wherein the seawater desalinating unit further comprises a brine tube, and the flow battery is connected to the brine tube and is adapted to convert chemical energy into electrical energy.

8. The device of claim 1, further comprising a controller disposed in the desalination and power generation chamber, wherein the coupling further comprises a break gear, and the controller is adapted to control the break gear to allow for or stop the rotation of the turbine.

9. The device of claim 2, the device further comprising a controller disposed in the desalination and power generation chamber, wherein the coupling further comprises a break gear, and the controller is adapted to control the break gear to allow for or stop the rotation of the turbine.

10. The device of claim 9, wherein a flow regulator is disposed in the pump chamber to regulate a slope angle of the swash plate with respect to the revolving shaft, and the controller is adapted to control the regulation of the flow regulator.

11. The device of claim 1, further comprising a rudder disposed on the end cover, wherein the rudder is adapted to adjust an orientation of the turbine.

12. The device of claim 2, further comprising a rudder disposed on the end cover, wherein the rudder is adapted to adjust an orientation of the turbine.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The invention is described hereinbelow with reference to accompanying drawings, in which:

(2) FIG. 1 is a schematic diagram of a device for sea water desalination and power generation in accordance with one embodiment of the invention;

(3) FIG. 2 is a sectional view taken from line A-A in FIG. 1; and

(4) FIG. 3 is a sectional view taken from line B-B in FIG. 1.

(5) In the drawings, the following reference numbers are used: 1. Tidal current turbine; 2. Coupling; 3. Revolving shaft; 4. Sealing assembly; 5. Body; 5a. Divider; 5b. End Cover; 6. Flow regulator; 7. Adjustable swash plate; 7a. Swash plate holder; 8. Plunger; 9. Cylinder; 10. Reset spring; 11. Multi-channel valve plate; 12. Outlet tube; 13. Inlet overflow valve; 14. Unsteady reverse osmosis membrane; 15. Freshwater tube; 16. Strong brine tube; 17. Outlet overflow valve; 18. Flow battery; 19. Brine discharge outlet; 20. Controller; 21. Seawater inlet; 22. Seawater pretreatment device; 23. Inlet tube; 24. Booster pump bearing; 25. Brake gear; 26. Rudder; 27. Support.

DETAILED DESCRIPTION OF THE EMBODIMENTS

(6) For further illustrating the invention, experiments detailing a device for sea water desalination and power generation are described below. It should be noted that the following examples are intended to describe and not to limit the invention.

(7) As shown in FIGS. 1-3, a device for sea water desalination and power generation comprises a horizontal shaft tidal current turbine 1 and a body 5. The body 5 comprises a chamber, a divider 5a, and an end cover 5b. The divider 5a and the end cover 5b are in fixed connection to the body. The divider 5a divides the chamber into a closed pumping chamber and a closed desalination and power generation chamber. The tidal current turbine 1 is connected to a revolving shaft 3 via a coupling 2. A booster pump is disposed in the pumping chamber and is driven by the revolving shaft 3. A sealing assembly 4 and a booster pump bearing 24 are disposed between the revolving shaft 3 and the body 5. The coupling 2 comprises a brake gear 25.

(8) The booster pump employs a plunger-type rotary pump. A swash plate holder 7a is disposed in the pump chamber and is in fixed connection to the body 5. The revolving shaft 3 is in fixed connection to a cylinder of the booster pump. A plunger 8 and a reset spring 10 are disposed in the cylinder 9 and cooperate with an adjustable swash plate 7 disposed in the swash plate holder 7a. A flow regulator 6 is disposed in the pump chamber to regulate a slope angle of the adjustable swash plate 7. A supporting bearing is disposed at one end of the revolving shaft 3 in the divider 5a. A plunger chamber in the cylinder 9 cooperates with the inlet tube 23 and the outlet tube 12 of a multi-channel valve plate 11.

(9) The desalination and power generation chamber comprises a seawater pretreatment device 22, a seawater desalinating unit comprising an unsteady reverse osmosis membrane 14, a flow battery 18, and a controller 20. The booster pump is connected to the seawater pretreatment device 22 via an inlet tube 23, and is connected to the seawater desalinating unit via an outlet tube 12. The seawater desalinating unit is connected to the flow battery 18 via a strong brine tube 16. An inlet overflow valve 13 is disposed at the outlet tube 12 of the booster pump, and an outlet overflow valve 17 is disposed at the strong brine tube 16.

(10) A streamlined guide is disposed between the body 5 and the tidal current turbine 1; a rudder is disposed in the proximity of the end cover 5b; and the body further comprises a support 27, a seawater inlet 21, a freshwater tube 15, and a brine discharge outlet 19.

(11) The working principle of the device for sea water desalination and power generation is summarized as follows. Natural sea water is introduced to the seawater pretreatment device 22 via the seawater inlet 21. The purified sea water flows into the multi-channel valve plate 11 via the inlet tube 23 of the booster pump. The tidal current drives the tidal current turbine 1 to rotate. The tidal current turbine 1 drives the revolving shaft 3 and the cylinder 9 to rotate via the coupling 2 with the support of the booster pump bearing. By the action of stationary adjustable swash plate 7 and the reset spring 10, the plunger 8 moves axially in the plunger chamber of the cylinder 9. Thus, the pressure of the sea water in the multi-channel valve plate 11 is boosted. The high pressure sea water flows into the seawater desalinating unit comprising the unsteady reverse osmosis membrane 14 via the outlet tube 12 and the inlet overflow valve 13. Part of the sea water is converted into freshwater when penetrating the reverse osmosis membrane, which is stored in the freshwater tube 15. Another part of the sea water is concentrated to yield high pressure strong brine which flows into the flow battery 18 via the strong brine tube 16 and the outlet overflow valve 17. The high pressure strong brine drives the pump in the flow battery to do work. Thus, the chemical energy is transformed into electric energy and stored. Thereafter, the strong brine is discharged into the ocean via a brine discharge outlet 19. During working, the sealing assembly 4 prevents the sea water from flowing into the body 5. When the pressure needs changing, the controller 20 regulates the flow regulator 6 to alter the slope angle of the adjustable swash plate 7. When the direction of the tidal current varies, the rudder can automatically modify the direction of the tidal current turbine 1. In extreme weather conditions, the controller 20 can control the brake gear 25 to stop the rotation of the tidal current turbine 1.

(12) While particular embodiments of the invention have been shown and described, it will be obvious to those skilled in the art that changes and modifications may be made without departing from the invention in its broader aspects, and therefore, the aim in the appended claims is to cover all such changes and modifications as fall within the true spirit and scope of the invention.