System where electricity generation efficiency is increased by means of liquids which have different densities

Abstract

A system for generating electricity from a high density liquid and a low density liquid is provided. The system includes a first liquid chamber, a first drive chamber, at least one permeable wall and at least one pressure retaining osmosis membrane, a first ejector, and a first liquid channel; and a second liquid chamber, a second drive chamber, at least one permeable wall and at least one pressure retaining osmosis membrane, a second ejector, and at least two electrodes.

Claims

1. A system for generating electricity from a high density liquid and a low density liquid, wherein the system comprises a first liquid chamber having a first inlet for taking the high density liquid as input; a first drive chamber provided in the first liquid chamber; at least one permeable wall having at least two ion selective membranes for providing an ion passage from the high density liquid to the first drive chamber and at least one pressure retaining osmosis membrane for providing a solvent passage from the high density liquid to a liquid with an increasing density in the first drive chamber; a first ejector, wherein the first ejector is in a venturi type and comprises a drive end connected hydraulically to the first drive chamber and a suction end and hydraulically connected to the first liquid chamber, and a spray end for providing an exiting of a liquid taken from the suction end and an exiting of a liquid taken from the drive end by a gaining pressure, wherein the suction end provides a suctioning when a pressure of the liquid in the drive end increases; and a first liquid channel connected to the first ejector, wherein the first liquid channel has a first outlet; wherein the system comprises a second liquid chamber having a second inlet for taking the low density liquid as input; a second drive chamber provided in the second liquid chamber; at least one permeable wall having at least two ion selective membranes for providing an ion passage from the low density liquid to the second drive chamber and at least one pressure retaining osmosis membrane for providing a solvent passage from the low density liquid to a liquid with an increasing density in the second drive chamber; a second ejector, wherein the second ejector is in a venturi type and comprises a drive end connected hydraulically to the second drive chamber and a suction end and hydraulically connected to the second liquid chamber, and a spray end for providing an exiting of a liquid taken from the suction end and an exiting of a liquid taken from the drive end by a gaining pressure, wherein the suction end provides a suctioning when a pressure of the liquid in the drive end increases; the spray end of the second ejector is connected to a second outlet; and at least two electrodes in at least one of the first liquid chamber and the second liquid chamber in order to transform a charge difference, formed by the permeable walls, into the electricity.

2. The system according to claim 1, wherein the system comprises at least one permeable wall, wherein the at least one permeable wall comprises at least one pressure retaining membrane and at least two ion selective membranes having opposite poles and provided between the first liquid channel and the second liquid chamber.

3. The system according to claim 2, wherein at least two permeable walls are provided between the first liquid channel and the second liquid chamber, and the ion selective membranes of the permeable walls are configured to allow a passage of ions having opposite poles with respect to each other.

4. The system according to claim 1, wherein at least one part of the first liquid channel is configured to pass through the second liquid chamber.

5. The system according to claim 4, wherein at least one of the at least two electrodes is provided in a manner contacting two liquids between the first liquid chamber and the second liquid chamber.

6. The system according to claim 1, wherein the first drive chamber comprises two permeable walls and the ion selective membranes of the two permeable walls are configured to allow a passage of ions having opposite poles with respect to each other.

7. The system according to claim 6, wherein at least two of the at least two electrodes are provided against the ion selective membranes in the first liquid chamber for providing a generation of current from an ion exchange formed by the opposite charged ion selective membranes.

8. The system according to claim 1, wherein the second drive chamber comprises two permeable walls and the ion selective membranes of the two permeable walls are configured to allow a passage of ions having opposite poles with respect to each other.

9. The system according to claim 8, wherein at least two of the at least two electrodes are provided against the ion selective membranes in the second liquid chamber for providing a generation of electricity from an ion exchange formed by the opposite charged ion selective membranes.

10. The system according to claim 1, wherein the system comprises an ion selective membrane support provided between the ion selective membranes and the liquids.

11. The system according to claim 1, wherein the permeable walls comprise membrane housings for a fixation of the ion selective membrane and the pressure retaining osmosis membranes.

12. The system according to claim 1, wherein an energy generation unit is provided for transforming a voltage difference in the at least two electrodes into the electricity.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) In FIG. 1, a representative view of the system is given.

(2) In FIG. 2, a more detailed representative view of the permeable wall is given.

REFERENCE NUMBERS

(3) 10 System 100 First liquid chamber 101 First inlet 110 First drive chamber 120 First ejector T drive end E suction end P spray end 130 First liquid channel 131 First outlet 200 Second liquid chamber 201 Second inlet 210 Second drive chamber 220 Second ejector 231 Second outlet 300 Permeable wall 310 Ion selective membrane 311 Ion selective membrane support 320 Pressure retaining osmosis membrane 321 Membrane housing 400 Electrode 500 Energy generation unit

DETAILED DESCRIPTION OF THE EMBODIMENTS

(4) In this detailed description, the subject matter is explained with references to examples without forming any restrictive effect only in order to make the subject more understandable.

(5) The present invention relates to a system (10) which provides generation of electricity by using density difference of a high density liquid and a low density liquid essentially having different densities and which does not use movable components and which consumes less energy.

(6) With reference to FIG. 1, the system (10) includes a first liquid chamber (100) for receiving high density liquid through a first inlet (101). Said first liquid chamber (100) has a first drive chamber (110). Said first drive chamber (110) includes at least one permeable wall (300) having at least one ion selective membrane (310) for providing ion passage from the high density liquid to the first drive chamber (110) by the first drive chamber (110), and at least one pressure retaining osmosis membrane (320) for providing solvent passage from the high density liquid to the liquid having increasing density in the first drive chamber (110).

(7) As known in the art, the ion selective membrane (310) provides passage of ions, which have a polarity, from the side where said ions are plenty to the side where said ions are less in number. For instance, the positive selective membrane provides passage of positive ions from the side where positive ions are plenty to the side where positive ions are less until the ions become equalized. It is used in inverse electrodialysis systems in the art. The pressure retaining osmosis membrane (320) provides solvent passage from the liquid with low density to the liquid with high density. For instance, when the sea water and the fresh water are separated by means of a pressure retaining osmosis membrane (320), water passes from the sea water to the fresh water, and the height of the fresh water increases, and if said fresh water is kept in a fixed volume, the pressure thereof increases.

(8) In a possible embodiment of the present invention, the first drive chamber (110) includes at least two permeable walls (300). The ion selective membrane (310) of one of the permeable walls (300) is selected to allow passage of ions having poles which are opposite with respect to the ion selective membrane (310) of the other one of the permeable walls (300). Ion passage occurs from the high density liquid to the liquid, which exists in the first drive chamber (110), by means of ion selective membranes (310). Solvent passage occurs to the liquid, which becomes denser since ion passage occurs, by means of pressure retaining membranes, and the pressure of the liquid which exists in the first drive chamber (110) increases.

(9) The first liquid chamber (100) includes a first ejector (120) which is in venturi type. The first ejector (120) has a drive end (T) connected to the first drive chamber (110), a suction end (E) which provides suctioning when pressured water comes from the drive end (T) and opened to the first liquid chamber (100), a spray end (P) which suctions the liquid at the suction end (E) when pressured liquid comes from the drive end (T) and which discharges together with the pressured liquid. The spray end (P) is connected to a first liquid channel (130). The first liquid channel (130) provides discharge of the high density liquid through a first outlet (131).

(10) The first liquid chamber (100) includes electrodes (400) provided in the vicinity of the ion selective membranes (310). These electrodes (400) provide transformation of the voltage difference, which results from changing of the ion balance by the high density liquid by means of the ion selective membranes (310), into electricity. The electrodes (400) are positioned against the ion selective membranes (310) in the first liquid chamber (100). An energy generation unit (500) is associated with the electrodes (400). The energy generation unit (500) can include components which provide rectification of the obtained current and passage thereof through various processes.

(11) The system includes a second liquid chamber (200) for taking the low density liquid through a second inlet (201). Said second liquid chamber (200) has a second drive chamber (210). Said second drive chamber (210) includes at least one permeable wall (300) having at least one ion selective membrane (310) for providing ion passage from the low density liquid to the liquid, which exists in the first drive chamber (110), by the second drive chamber (210), and at least one pressure retaining osmosis membrane (320) for providing solvent passage from the low density liquid to the liquid, having increasing density, in the first drive chamber (110).

(12) In a possible embodiment of the present invention, the second drive chamber (210) includes at least two permeable walls (300). The ion selective membrane (310) of one of the permeable walls (300) is selected in a manner allowing passage of ions which have opposite pole with respect to the ion selective membrane (310) of the other one of the permeable walls (300). Ion passage occurs from the low density liquid to the liquid, which exists in the second drive chamber (210), by means of ion selective membranes (310). Solvent passage occurs to the liquid, which becomes denser since ion passage occurs, by means of the pressure retaining membranes, and the pressure of the liquid which exists in the second drive chamber (210) increases.

(13) The second liquid chamber (200) includes a second ejector (220) which is in venturi type. The second ejector (220) has a drive end (T) connected to the second drive chamber (210), a suction end (E) which provides suctioning when pressured water comes from the drive end (T) and opened to the second liquid chamber (200), a spray end (P) which suctions the liquid at the suction end (E) when pressured liquid comes from the drive end (T) and which discharges together with the pressured liquid. The spray end (P) provides discharge of the liquid by means of a second outlet (231).

(14) The second liquid chamber (200) includes electrodes (400) provided in the vicinity of ion selective membranes (310). These electrodes (400) provide transformation of the voltage difference, which result from changing of the ion balance by the high density liquid by means of the ion selective membranes (310), into electricity. The electrodes (400) are positioned against the ion selective membranes (310) in the second liquid chamber (200).

(15) In a possible embodiment of the present invention, the first liquid channel (130) passes through the second liquid chamber (200). The first liquid channel (130) includes at least one permeable wall (300).

(16) The ion selective membrane (310) of one of the permeable walls (300) is selected in a manner allowing passage of ions which have opposite poles with respect to the ion selective membrane (310) of the other one of the permeable walls (300). Ion and solvent passage occurs by means of walls through the first liquid channel (130) to the second liquid chamber (200). Thus, the pressure of the second liquid and the ion amount also increase. The second drive chamber (210) exerts more pressure to the second ejector (220).

(17) In a possible embodiment of the present invention, one of the electrodes (400), which exists in the liquid chamber (200), is provided between the first liquid channel (130) and the second drive chamber (210). One of the electrodes (400), which exist in the first liquid chamber (100), is provided on a mutual wall in a manner both contacting the liquid which exists in the first liquid chamber (100) and the liquid which exists in the second liquid chamber (200).

(18) The protection scope of the present invention is set forth in the annexed claims and cannot be restricted to the illustrative disclosures given above, under the detailed description. It is because a person skilled in the relevant art can obviously produce similar embodiments under the light of the foregoing disclosures, without departing from the main principles of the present invention.