BG66872B1 - Method and installation for direct electricity production from bottom marine water containing sulphides - Google Patents

Abstract

The method and the installation use a renewable energy source. There are no harmful emissions into the water and air during operation. The working process is constant, the power is regulated smoothly, no fuel and other consumables are used, the sea is cleaned of dissolved sulphides, and the dissolved oxygen increases in the surface layer. Seawater containing sulphides is pumped from the bottom layer, from which an anolyte is obtained. Sulphide-free seawater is pumped from the surface layer to form catholyte. The anolyte and catholyte are fed to a fuel cell, at the poles of which is generated electricity. Part of the electricity produced is used to power the installation, and the rest is fed into the external electrical network. The process of oxidation of sulphides to sulphates in the fuel cell practically does not generate heat and the conversion of chemical energy into electricity is practically complete.

Description

Field of application

The method and installation for direct extraction of electricity from bottom seawater containing sulfides are applicable in electricity and environmental protection.

BACKGROUND OF THE INVENTION

Indirect methods are known for obtaining electricity from seawater containing sulfides. Initially, hydrogen sulfide and / or hydrogen are extracted from seawater containing sulfides. The extracted gases are burned, which produces heat energy. It is transformed into mechanical energy and electrical energy is extracted from it. The disadvantages of these methods are in the many processes of energy conversion, which significantly reduces the overall efficiency, and hence the economic benefits of their application. Also, the extraction and combustion of gases result in harmful emissions, the reduction of which makes the technology more expensive.

Indirect methods are known in which gases extracted from seawater containing sulphides are fed as fuel to a fuel cell from which heat and / or electricity is generated.

The disadvantages of these methods are again harmful emissions and low energy yield.

There is no known method and installation for direct production of electricity from bottom seawater containing sulfides, which directly generates electricity without partial or complete passage through thermal and / or mechanical energy.

Technical essence of the invention

The object of the invention is to provide a method and an installation for the direct production of electricity from bottom seawater containing sulphides.

This problem is solved by creating a method for direct production of electricity from bottom seawater containing sulfides, by pumping seawater from the bottom layer of the sea, for example in the Black Sea, containing sulfides to obtain a solution with concentrations close to that of saturated aqueous sulfide solution, which accumulates and feeds as an anolyte into the anode chamber of the fuel cell. The waste water is returned immediately above the bottom layer of the sea containing sulfides. At the same time, the seawater from the sulfide-free surface layer is pumped and enriched with oxygen by aeration and used as a catholyte in the cathode chamber of the fuel cell. The sulfides contained in the anolyte are converted into sulphates. The oxygen contained in the catholyte is reduced to hydroxyl anions, whereby the fuel cell produces electricity, which is converted into alternating voltage and fed into an external electrical network. The spent anolyte and catholyte are returned to the sea at a depth just above the bottom layer containing sulfides. The sea is purified of sulfides and the surface layer of seawater, which does not contain sulfides, is increased.

It is possible, in addition, to recover from the spent anolyte containing a minimum amount of sulphides a solution close to a saturated aqueous sulphide solution, which is fed to supply the anode chamber of the fuel cell. The waste water is returned to the sea at a depth just above the bottom layer containing sulfides.

The installation for direct production of electricity from bottom seawater containing sulfides, implementing the method, has a closed floating housing, from which descends a first suction pipe with a watertight wall, the inlet of the first suction pipe is in the bottom water layer containing sulfides . The outlet of the first suction pipe is discharged into a first pump, the first connecting pipe connecting the outlet of the first pump to a third enrichment inlet valve. A second connecting pipe connects the first outlet valve to the inlet of the fourth pump. A third connecting pipe connects the outlet of the fourth pump to a tank. A fourth connecting pipe connects the outlet of the tank to the first inlet valve of the fuel cell. The inlet of the third suction pipe is discharged into a second suction pipe. The output of

Descriptions of issued patents for inventions № 05.2 / 31.05.2019 a third suction pipe is discharged into the inlet of a third pump, the outlet of which is connected to a fourth inlet valve of the enrichment, which has a first filter, a second outlet valve is discharged into a second outlet pipe, whose outlet is discharged into the inlet of a first outlet pipe, with a watertight wall, the outlet of which is immediately above the bottom layer containing sulphides. The inlet of a second suction pipe is discharged into the surface layer of the sea, which does not contain sulfides. The outlet of a second suction pipe is discharged into the inlet of a second pump, the outlet of which is connected by a fifth connecting pipe to the inlet of an aerator, the outlet of which is connected to a second inlet valve. The fuel cell has an anode chamber and a cathode chamber, the anode chamber having a first inlet valve. The outlet of the third outlet pipe is discharged into the water in the first outlet pipe. The cathode chamber has a second inlet valve. The outlet of the fourth outlet pipe is discharged into the inlet of the first outlet pipe. The anode and cathode of the fuel cell are connected by an inverter to the external electrical network. The installation also has a control unit that is connected in both directions to the inverter and unidirectionally to the controlled first inlet valve, second inlet valve, third inlet valve, fourth inlet valve, first outlet valve, second outlet valve, aerator, first pump, second pump, third pump and fourth pump, such as first pump, second pump, third pump, fourth pump, first inlet valve, second inlet valve, third inlet valve, fourth inlet valve, first outlet valve, inverter and aerator are connected to the external mains.

It is possible for the installation for direct production of electricity from bottom seawater containing sulfides to have a third outlet pipe connected to the fifth inlet valve of the first utilizer and to the sixth inlet valve of the second utilizer, as a third outlet valve is connected to the inlet of the fifth pump. an outlet is connected by a sixth connecting pipe to a third connecting pipe, a fourth outlet valve being connected to the inlet of the sixth pump, the outlet of which is connected by a seventh connecting pipe to a third connecting pipe and a diversion from a third suction pipe to the seventh pump inlets. and an eighth pump, the outlet of the seventh pump being connected to the seventh inlet valve of the enricher, and the outlet of the eighth pump being connected to the eighth inlet valve of the enrichment, and the fifth outlet valve and the sixth outlet valve being connected to a fifth outlet pipe. discharged at the inlet of the first outlet pipe, and the control unit is connected in one direction to the controlled fifth inlet valve, seventh inlet valve, third outlet n valve, fifth outlet valve, sixth inlet valve, eighth inlet valve, fourth outlet valve, sixth outlet valve, seventh pump, eighth pump, fifth pump and sixth pump, such as fifth inlet valve, seventh inlet valve, third outlet valve, fifth outlet valve, sixth inlet valve, eighth inlet valve, fourth outlet valve, sixth outlet valve, seventh pump, eighth pump, fifth pump and sixth pump are connected to the external mains.

Explanation of the attached figures

The invention is explained in more detail, with an exemplary embodiment shown in the figures, where: figure 1 represents a plant for direct production of electricity from bottom seawater containing sulfides, with an enricher, aerator, tank and fuel cell;

Figure 2 - installation for direct production of electricity from bottom seawater containing sulfides, with enrichment, aerator, tank, fuel cell and two utilizers.

An exemplary embodiment of the invention

The method for direct production of electricity from bottom seawater containing sulphides by pumping and enriching seawater from the bottom layer of the sea, for example "Black Sea", containing sulphides to obtain a solution with concentrations close to that of saturated aqueous sulfide solution, which accumulates and feeds as an anolyte into the anode chamber of the fuel cell. The waste water is returned immediately above the bottom layer of the sea containing sulfides. At the same time, the seawater from the sulfide-free surface layer is pumped and enriched with oxygen by aeration and fed as a catholyte into the cathode chamber of the fuel cell. The sulfides contained in the anolyte are converted into sulphates. The oxygen contained in the catholyte is reduced to hydroxyl anions, whereby the fuel cell produces electricity, which is converted into alternating voltage and fed into an external electrical network. Worn out

Descriptions of issued patents for inventions № 05.2 / 31.05.2019 anolyte and catholyte are returned to the sea at a depth immediately above the bottom layer containing sulfides. The sea is purified of sulfides and the surface layer of seawater, which does not contain sulfides, is increased.

It is possible, in addition, to recover from the spent anolyte containing a minimum amount of sulphides a solution close to a saturated aqueous sulphide solution, which is fed to the anode chamber of the fuel cell. The waste water is returned to the sea at a depth just above the bottom layer containing sulfides.

The installation for direct production of electricity from bottom seawater containing sulfides, implementing the method, has a closed floating housing 1, from which descends a first suction pipe 2, with a watertight wall, the inlet of the first suction pipe 2 is in the bottom water layer 30 containing sulfides. The outlet of the first suction pipe 2 is discharged into the first pump 3, the first connecting pipe 4.1 connecting the outlet of the first pump 3 to the third inlet valve 15.1 of the enricher 15. And the second connecting pipe 4.2 connects the first outlet valve 15.3 to the inlet of the fourth pump 18. A third connecting pipe 4.3 connects the outlet of the fourth pump 18 to the tank 16. A fourth connecting pipe 4.4 connects the outlet of the tank 16 to the first inlet valve 5.5 of the fuel cell 5. The inlet of the third suction pipe 23 is discharged into a second suction pipe 28. The outlet of the third suction pipe 23 is discharged into the inlet of a third pump 17, the outlet of which is connected to a fourth inlet valve 15.2 of the enrichment 15, which has a first filter 15.5, and a second outlet valve 15.4 is discharged into a second outlet pipe 26, the outlet of which is discharged into the inlet of a first outlet pipe 11, with a watertight wall, the outlet of which is immediately above the bottom layer 30 containing sulfides. The inlet of the second suction pipe 28 is discharged into the surface layer of the sea 29, which does not contain sulfides. The outlet of a second suction pipe 28 is discharged into the inlet of a second pump 9, the outlet of which is connected by a fifth connecting pipe 8 to the inlet of an aerator 10, the outlet of which is connected to a second inlet valve 5.6. The fuel cell 5 has an anode chamber 5.1 and a cathode chamber 5.2, the anode chamber 5.1 having a first inlet valve 5.5. The outlet of the third outlet pipe 6 is discharged into the water in the first outlet pipe 11. The cathode chamber 5.2 has a second inlet valve 5.6. The outlet of the fourth outlet pipe 7 is discharged into the inlet of the first outlet pipe 11. The anode 5.3 and the cathode 5.4 of the fuel cell 5 are connected by an inverter 12 to the external mains 13. The installation also has a control unit 14 which is connected in both directions to the inverter 12, and in one direction with the controlled first inlet valve 5.5, second inlet valve 5.6, third inlet valve 15.1, fourth inlet valve 15.2, first outlet valve 15.3, second outlet valve 15.4, aerator 10, first pump 3, second pump 9, third pump 17 and a fourth pump 18, such as a first pump 3, a second pump 9, a third pump 17, a fourth pump 18, a first inlet valve 5.5, a second inlet valve 5.6, a third inlet valve 15.1, a fourth inlet valve 15.2, a first outlet valve 15.3, a second outlet valve 15.4, the inverter 12 and the aerator 10 are connected to the external electrical network 13.

It is possible for the direct seawater electricity generation installation containing sulphides to have a third outlet pipe 6 connected to a fifth inlet valve 21.1 of the first utilizer 21 and a sixth inlet valve 22.1 of the second utilizer 22, with a third outlet valve 21.3 connected to the inlet of the fifth pump 24, the outlet of which is connected via a sixth connecting pipe 4.5 to a third connecting pipe 4.3, the fourth outlet valve 22.3 being connected to the inlet of the sixth pump 25 whose outlet is connected by a seventh connecting pipe 4.6 to a third connecting pipe 4.3 and a branch 23.1 from the third suction pipe 23 is connected to the inlets of the seventh pump 19 and the eighth pump 20, the outlet of the seventh pump 19 is connected to the seventh inlet valve 21.2 of the enrichment 21 and the outlet of the eighth pump 20 is connected to the eighth inlet valve 22.2 of the enrichment 22, and the fifth outlet valve 21.4 and the sixth outlet valve 22.4 are connected to a fifth outlet pipe 27, the outlet of which is discharged into the inlet of the first outlet pipe 11, and controlled unit 14, is connected in one direction to the controlled fifth inlet valve 21.1, seventh inlet valve 21.2, third outlet valve 21.3, fifth outlet valve 21.4, sixth inlet valve 22.1, eighth inlet valve 22.2, fourth outlet valve 22.3, sixth outlet valve 22.4, seventh pump 19, eighth pump 20, fifth pump 24 and sixth pump 25, such as fifth inlet valve 21.1, seventh inlet valve 21.2, third outlet valve 21.3, fifth outlet valve 21.4, sixth inlet valve 22.1, eighth inlet valve 22.2, fourth outlet valve 22.3 , sixth outlet valve 22.4, seventh pump 19, eighth pump 20, fifth

Descriptions of issued patents for inventions № 05.2 / 31.05.2019 pump 24 and sixth pump 25 are connected to the external electrical network 13.

Action of the invention

The method for direct production of electricity from bottom sea water containing sulfides is realized by the installation for production of electricity from a reservoir, using bottom sea water containing sulfides, shown in fig. 1.

The first pump 3 sucks water from the first inlet pipe 2 and thus lifts the water from the bottom layer containing sulfides 30 to the installation. This water is enriched to a solution close in concentration to saturated aqueous sulfide solution in the enricher 15. It operates sequentially over time in three different modes. In mode I, the fourth inlet valve 15.2 and the first outlet valve 15.3 are closed, and the third inlet valve 15.1 and the second outlet valve 15.4 are open. The water passes freely through filter 15.5 and sulfide ions accumulate in it. Through a second outlet pipe 26, water is poured freely into a first outlet pipe 11 at a depth immediately above the bottom layer containing sulfides 30. A sensor not shown in FIG. 1 monitors the concentration of sulphides in the water after the second outlet valve 15.4. When the concentration of sulfides exceeds a maximum permissible level, the first pump 3 is stopped and the enricher 15 switches to mode II operation. In this mode, the third inlet valve 15.1, the first outlet valve 15.3 and the second outlet valve 15.4 are closed, and the fourth inlet valve 15.2 is open. A third pump 17 flushes the filter to obtain in the enricher 15 an anolyte close in concentration to a saturated solution of sulfides in water. Then, in the presence of free volume in the tank 16, by means of a level sensor not shown in FIG. 1, which monitors the level of the anolyte in the tank 16, the enrichment 15 is allowed to operate in mode III. In this mode, the third inlet valve 15.1, the fourth inlet valve 15.2 and the second outlet valve 15.4 are closed and the first outlet valve 15.3 is open. With the fourth pump 18 the extracted anolyte is transferred to tank 16. After finishing the work in mode III the enrichment returns to work in mode I.

The fuel cell 5 consists of a number of fuel elements connected in series electrically, so that the output voltage of the fuel cell 5 corresponds to the standard values adopted in the operation of renewable energy sources. In FIG. 1 for illustration is shown a fuel cell 5 with only one fuel element, but the anode chamber or cathode chamber should be understood as the simultaneous operation of the anode chambers or the cathode chambers of all fuel elements, and the anode or cathode should be understood as connected in series anodes or cathodes of all fuel elements. From the tank 16 the anolyte is fed through the first inlet valve 5.5 in the anode chambers 5.1 of the fuel cell 5. Simultaneously, a second pump 9 sucks from sufficient depth fresh water from the surface layer, which does not contain sulfides. It is passed through aerator 10, where it is enriched with oxygen and as a catholyte is fed through a second inlet valve 5.6 in the cathode chambers 5.2 of the fuel cell 5. In the anode chambers 5.1 on the catalyst deposited on the anodes 5.3 sulfides contained in anolytes, oxidize and turn into sulfates. In the cathode chambers 5.2 on the catalyst supported on the cathodes 5.4 the oxygen contained in the catholyte is reduced to hydroxyl anions. The spent anolyte containing sulphates through a third outlet pipe 6 and the spent catholyte through a fourth outlet pipe 7 are discharged through a first outlet pipe 11 into the sea just above the bottom layer containing sulphides 30.

During the operation of the fuel cell 5 between the anode 5.3 and the cathode 5.4 an electric potential difference or constant voltage occurs.

All equipment requiring power supply is initially supplied by the external mains. When the installation is operating, the control unit 14 receives data from voltage sensors not shown in fig. 1, monitoring the voltage between the anode 5.3 and the cathode 5.4 of the fuel cell. Based on these data, the control unit 14 supplies to the first inlet valve 5.5 and the second inlet valve 5.6 control signals proportional to the difference between the values of the set and current voltage of the fuel cell 5. Thus the output voltage is regulated depending on consumption infinitely throughout fuel cell power range.

The DC voltage thus obtained is converted into a standard change by the inverter 12

Descriptions of issued patents for inventions № 05.2 / 31.05.2019 left voltage with a frequency corresponding to the external electrical network 13. One part of the produced energy supplies the equipment of the installation, and the rest is given to the external electrical network 13.

The installation in the variant of fig. 2 works as the installation of FIG. 1, but the presence of a first utilizer 21 and a second utilizer 22 allows a further saturated sulfide solution to be obtained from the spent anolyte exiting the anode chamber 5.1 of the fuel cell 5, which contains a certain amount of sulfides. The spent anolyte is simultaneously passed through the first recycle 21 and the second recycle 22. The control unit 14 controls the recyclers sequentially when operating in three modes. In mode I of the first utilizer 21, the seventh inlet valve 21.2 and the third outlet valve 21.3 are closed, and the fifth inlet valve 21.1 and the fifth outlet valve 21.4 are open. The water passes freely through filter 21.5 and sulfide ions accumulate in it. Through a fifth outlet pipe 27, water is poured freely into a first outlet pipe 11 and thence into the sea immediately above the bottom layer containing sulphides. A sensor not shown in FIG. 2, monitor the concentration of sulfides in the water after the fifth outlet valve 21.4. When the concentration of sulphides exceeds a limit level, the first utilizer 21 switches to mode II operation, provided that the utilizer 22 operates in mode I. The fifth inlet valve 21.1, the third outlet valve 21.3 and the fifth outlet valve 21.4 are closed, and seventh inlet valve 21.2 is open. Through it, a seventh pump 19 flushes the filter in order to obtain in the first utilizer 21 an anolyte close in concentration to a saturated solution of sulfides in water. If there is a free volume in the tank, switch to mode III. In this case, the fifth inlet valve 21.1, the seventh inlet valve 21.2 and the fifth outlet valve 21.4 are closed, and the third outlet valve 21.3 is open. With the fifth pump 24 we pump the obtained anolyte into tank 16. Then the first utilizer 21 goes to work in mode I. The second utilizer 22 works in mode I, as the eighth inlet valve 22.2 and the fourth outlet valve 22.3 are closed, and the sixth inlet valve 22.1 and sixth outlet valve 22.4 are open. The water passes freely through the filter 22.5 and sulfide ions accumulate in it. Through a second outlet pipe 26, the water is poured into a first outlet pipe 11 and thence into the sea immediately above the bottom layer containing sulphides. A sensor not shown in FIG. 2, monitor the concentration of sulphides in the water after the sixth outlet valve 22.4. When the concentration of sulphides exceeds a maximum permissible level and the first utilizer 21 is in mode I, the second utilizer 22 switches to mode II operation. In this case, the sixth inlet valve 22.1, the fourth outlet valve 22.3 and the sixth outlet valve 22.4 are closed, and the eighth inlet valve 22.2 is open. Through it, an eighth pump 20 flushes the filter in order to obtain in the enricher 22 an anolyte close in concentration to a saturated solution of sulfides in water. In mode III, valves 5.1, 5.2 and 5.4 are closed and valve 5.3 is open. The sixth pump 25 pumps the obtained anolyte into the tank 16. Thus, modes II and III in the first utilizer 21 are performed only during operation in mode I of the second utilizer 22, and modes II and III in the second utilizer 22 operate only during of operation in mode I of the first utilizer 21. The control unit 14 on the basis of the feedback from the level sensors in the enrichers and the tank and the time diagram for operation of the enrichment in the different modes makes the control actions to the fifth inlet valve 21.1, seventh inlet valve 21.2, third outlet valve 21.3, fifth outlet valve 21.4, sixth inlet valve 22.1, eighth inlet valve 22.2, fourth outlet valve 22.3, and sixth outlet valve 22.4, as well as seventh pump 19, eighth pump 20, fifth pump 24 and sixth pump 25.

In the production of electricity from seawater containing sulphides, after the oxidation of sulphides in the fuel cell, the same seawater with sulphates dissolved in it is obtained as a waste product. Sulfates are part of the natural salts of seawater and are used for the microbial metabolism of sulfate-reducing bacteria living at greater depths. These bacteria reduce sulfates to sulfides. Therefore, the method and installation for electricity generation fully meet the conditions for a renewable energy source.

The installation during operation moves seawater from layers into the sea at different depths. This reduces the vertical stratification of the sea, ie. reduces the difference in salinity of the different layers and promotes the penetration of oxygen into the depths. So besides removing

Descriptions of issued patents for inventions № 05.2 / 31.05.2019 of sulfides in depth, in their place the presence of oxygen is ensured. This contributes to a sharp increase in biodiversity, the restoration of almost extinct species of plants and animals over the centuries and a general increase in the flora and fauna of the sea.

The plant converts the energy obtained from the oxidation of sulphides into sulphates practically completely into electricity, thus avoiding the losses from conversion into thermal and / or mechanical energy to generate electricity.

The operation of the installation does not require technological use of additional reagents, consumables and raw materials.

Unlike solar parks, wind farms, hydropower plants and other renewable energy sources, the installation can operate continuously and does not require the construction of replacement capacity. This makes it an efficient source of electricity, combining the advantages of renewable energy sources, fossil fuel energy sources and nuclear power plants.

The installation can be adjusted in power practically in its entire range of operation, which allows it to meet the conditions for primary, secondary and tertiary regulation of the system at the same time. The time for commissioning of the installation from standby (cold reserve) to connection to the network is of the order of 100 milliseconds. Only battery-powered capacities meet this condition. The installation does not produce reactive energy.

The plant does not use fuel, thus the cost of electricity produced does not depend on fluctuations in fuel prices on the international market.

The technological process allows installations on floating platforms to work without on-duty personnel, being controlled remotely.

If necessary, the installation can be moved to different connection points of the external electrical network.

The cost of energy extracted depends practically only on the initial investment and a small part of the current maintenance, which allows long-term cost planning.

In order to stop the rise in the level of waters containing sulphides, for example in the Black Sea, it is necessary to introduce installations with a capacity of at least 10000 MW, which will operate continuously. To reduce the level by 5 m per year, it is necessary to introduce at least another 10,000 MW of installations.

The Black Sea resource allows the simultaneous operation of installations with a capacity of 50,000 MW continuously for 50 years. This would provide 10% of the electricity needed annually, for example, in almost all European countries. As a result, the aerobic zone of life in the Black Sea would expand from 200 sh to 1000 sh depth.

No harmful emissions are released into the air and water during the operation of the installation. The process of oxidation of sulfides to sulfates in the fuel cell practically does not generate heat energy, that is, the process of electricity generation is cold. The absence of external moving parts during the operation of the floating platform excludes mechanical impact on the marine flora and fauna. Due to the lack of oxygen, there are no aerobic life forms in the bottom water and when this water passes through the installation there is no impact on animals and plants.

There are no aerobic life forms in the spent anolyte discharge zone, and the sulphates contained in it are natural salts of seawater and do not pose a risk of chemical pollution. Spent catholyte, which is unaltered seawater with a slightly alkaline reaction (pH between 7 and 8), also does not cause contamination.

The amount of working water contained in the installation is small compared to the surrounding seawater and in the event of an accident or destruction of the floating platform there is no environmental risk of contamination of surface water and air.

Claims (4)

Method for direct production of electricity from bottom seawater containing sulphides, characterized in that seawater from the bottom layer of the sea containing sulphides is pumped and enriched to obtain a solution close in concentration to a saturated aqueous solution of sulphides, which accumulates and feeds as an anolyte into the anode chamber of the fuel cell, and the waste water is returned directly above the seabed bottom layer containing sulphides, while the seawater from the sulphide-free surface layer is pumped and enriched with oxygen by aeration, then fed as a catholyte into the cathode chamber of the fuel cell, as the sulfides contained in the anolyte are converted into sulfates, and the oxygen contained in the catholyte is reduced to hydroxyl anions, whereby the fuel cell produces electricity, which is converted into alternating voltage and supplied to the external electrical network, and the spent anolyte and catholyte are returned to brother in the sea at a depth immediately above the bottom layer containing sulfides, as the sea is cleaned of sulfides and the surface layer of sea water not containing sulfides increases. Method for direct production of electricity from bottom seawater containing sulphides according to claim 1, characterized in that a solution close in concentration to a saturated aqueous solution of sulphides is further recovered from the spent anolyte containing a minimum amount of sulphides. is fed to the anode chamber of the fuel cell, and the waste water is returned to the sea at a depth immediately above the bottom layer containing sulfides. 3. Installation for the direct production of electricity from bottom seawater containing sulphides, characterized in that it comprises a closed floating hull (1) from which descends a first suction pipe (2), with a watertight wall, such as the inlet of the first suction pipe (2) is in the bottom water layer (30) containing sulfides, and the outlet of the first suction pipe (2) is discharged into the first pump (3), as the first connecting pipe (4.1) connects the outlet of the first pump (3). ) with a third inlet valve (15.1) of an enricher (15), as a second connecting pipe (4.2) connects the first outlet valve (15.3) with the inlet of the fourth pump (18), as a third connecting pipe (4.3) connects the outlet of the fourth pump 18) with a tank (16), as a fourth connecting pipe (4.4) connects the outlet of the tank (16) with the first inlet valve (5.5) of the fuel cell (5), and the inlet of the third suction pipe (23) is discharged into a second suction pipe. pipe (28), and the outlet of a third suction pipe (23) is discharged into the inlet of a third pump (17), whose an outlet is connected to a fourth inlet valve (15.2) of the enrichment (15), which has a first filter (15.5), the second outlet valve (15.4) being discharged into a second outlet pipe (26), the outlet of which is discharged into the inlet of a first outlet a pipe (11) with a watertight wall, the outlet of which is immediately above the bottom layer (30) containing sulphides, and the inlet of a second suction pipe (28) is discharged into the surface layer of the sea (29), which does not contain sulphides. , the outlet of a second suction pipe (28) being discharged into the inlet of a second pump (9), the outlet of which is connected by a fifth connecting pipe (8) to the inlet of an aerator (10), the outlet of which is connected to a second inlet valve (5.6). ), as the fuel cell (5), has an anode chamber (5.1) and a cathode chamber (5.2), the anode chamber (5.1) has a first inlet valve (5.5) and a third outlet pipe (6), the outlet of which is discharged into the inlet of the first outlet pipe (11), and the cathode chamber (5.2) has a second inlet valve (5.6), and a fourth outlet pipe (7), the outlet of which is tsn in the inlet of the first outlet pipe (11), as the anode (5.3) and the cathode (5.4) of the fuel cell (5) are connected by an inverter (12) to the external electrical network (13), and the installation also has a control unit ( 14), which is connected in both directions to the inverter (12), and unidirectionally to the controlled first inlet valve (5.5), second inlet valve (5.6), third inlet valve (15.1), fourth inlet valve (15.2), first outlet valve (15.3). ), second outlet valve (15.4), aerator (10), first pump (3), second pump (9), third pump (17) and fourth pump (18), as first pump (3), second pump (9) , third pump (17), fourth pump (18), first inlet valve (5.5), second inlet valve (5.6), third inlet valve (15.1), fourth inlet valve (15.2), first outlet valve (15.3), second outlet valve valve (15.4), inverter (12) and aerator (10) are connected to an external electrical network (13). Descriptions of issued patents for inventions № 05.2 / 31.05.2019 Installation for direct production of electricity from seawater containing sulfides according to claim 3, characterized in that a third outlet pipe (6) is connected to a fifth inlet valve (21.1) of the first utilizer (21) and a sixth inlet valve (22.1) of a second recycler (22), the third outlet valve (21.3) being connected to the inlet of a fifth pump (24), the outlet of which is connected by a sixth connecting pipe (4.5) to a third connecting pipe (4.3), as a fourth an outlet valve (22.3) is connected to the inlet of the sixth pump (25), the outlet of which is connected by a seventh connecting pipe (4.6) to a third connecting pipe (4.3) and a deviation (23.1) from a third suction pipe (23) is connected to the inlets of the seventh pump (19) and the eighth pump (20), the outlet of the seventh pump (19) being connected to the seventh inlet valve (21.2) of the enricher (21) and the outlet of the eighth pump (20) being connected to the eighth inlet enrichment valve (22.2) (22) and the fifth outlet valve (21.4) and the sixth outlet valve (22.4) are connected to the fifth outlet a supply pipe (27), the outlet of which is discharged into the inlet of the first outlet pipe (11), and the control unit (14) is connected in one direction to the controlled fifth inlet valve (21.1), seventh inlet valve (21.2), third outlet valve ( 21.3), fifth outlet valve (21.4), sixth inlet valve (22.1), eighth inlet valve (22.2), fourth outlet valve (22.3), sixth outlet valve (22.4), seventh pump (19), eighth pump (20), fifth pump (24) and sixth pump (25), such as fifth inlet valve (21.1), seventh inlet valve (21.2), third outlet valve (21.3), fifth outlet valve (21.4), sixth inlet valve (22.1), eighth inlet valve valve (22.2), fourth outlet valve (22.3), sixth outlet valve (22.4), seventh pump (19), eighth pump (20), fifth pump (24) and sixth pump (25) are connected to the external mains (13 ).