CN215907999U - Marine hydrogen production system methyl alcohol storage tank platform based on nuclear power, wind-powered electricity generation combine together - Google Patents

Abstract

A nuclear power and wind power combined offshore hydrogen production and methanol production storage cabin platform comprises a floating platform floating on the sea, wherein a nuclear power device, a power generation module and a power distribution module are arranged at one end of the floating platform and below a deck of the floating platform, the nuclear power device is sequentially connected with the power generation module and the power distribution module through pipelines, and a methanol storage cabin and a carbon dioxide storage cabin are further arranged below the deck of the floating platform. A seawater desalination device, an electrolytic hydrogen production module, a carbon dioxide capture module and a methanol preparation module are arranged above the deck of the floating platform, the seawater desalination device, the electrolytic hydrogen production module, the methanol preparation module and the carbon dioxide storage cabin are sequentially connected through pipelines, and a branch pipeline extending out of the carbon dioxide capture module is connected with the methanol preparation module. The offshore nuclear energy is utilized to prepare the methanol, the nuclear energy and the electric power generated by wind energy can be efficiently utilized, the high-load operation can be realized, the electric energy can be reasonably and effectively utilized to prepare the methanol on the sea, and the zero carbon emission in the whole process can be achieved.

Description

Marine hydrogen production system methyl alcohol storage tank platform based on nuclear power, wind-powered electricity generation combine together

Technical Field

The invention relates to the field of ship construction and design, in particular to a platform which takes nuclear energy as power and can prepare and store methanol on the sea.

Background

Most of the existing internal energy engines adopt fossil energy as fuel, a large amount of carbon can be released into the atmosphere, the existing fossil energy cannot realize zero carbon emission, and nuclear power is one of ideal clean energy sources as a route map and a target energy for realizing carbon emission reduction and carbon neutralization.

The onshore construction of a methanol synthesis plant is limited by a plurality of factors such as land use, site selection, investment and the like, and the offshore floating hydrogen production and ammonia synthesis and liquefaction storage platform can realize the source and supply of distributed, miniaturized and low-risk clean fuels.

The offshore wind power grid depends on natural wind resources, has the advantage of large generating capacity, and also has the problem that a large amount of redundant electric energy cannot be effectively utilized at idle time. The nuclear power methanol production and storage platform needs a large amount of electric energy, idle electric energy of a wind power grid can be utilized, and meanwhile, the platform can be used as an offshore power station to supplement electric energy for the wind power grid in the electricity utilization peak of the wind power grid.

Disclosure of Invention

In order to solve the problems, the invention provides a nuclear power and wind power combined offshore hydrogen production and methanol production storage cabin platform, which aims to achieve the aim of producing methanol by utilizing wind power or nuclear power or combining wind power and nuclear power at sea, and adopts the technical scheme that:

a marine hydrogen and methanol production storage cabin platform based on nuclear power and wind power combination comprises a floating platform floating on the sea, wherein a nuclear power device, a power generation module and a power distribution module are arranged at one end of the floating platform and below a deck of the floating platform, an isolation empty cabin is arranged among the power generation module, the power distribution module and the nuclear power device, the nuclear power device is sequentially connected with the power generation module and the power distribution module through pipelines, and a carbon dioxide storage cabin and a methanol storage cabin are further arranged below the deck of the floating platform.

A seawater desalination device, an electrolytic hydrogen production module, a methanol production module and a carbon dioxide capture module are arranged above a deck of the floating platform, the seawater desalination device, the electrolytic hydrogen production module and the methanol production module are sequentially connected through pipelines, a branch pipeline extending out of the air nitrogen production module is connected with the carbon dioxide capture module, and the power distribution module is respectively connected with the seawater desalination device, the electrolytic hydrogen production module, the methanol production module and the carbon dioxide capture module through pipelines. The power distribution module is connected with the wind power grid through a cable.

According to the offshore hydrogen production and methanol production storage cabin platform based on combination of nuclear power and wind power, furthermore, a transformer substation is arranged between the power distribution module and the wind power grid, and the power distribution module, the transformer substation and the wind power grid are sequentially connected through a cable.

According to the offshore hydrogen and methanol production storage cabin platform based on the combination of nuclear power and wind power, furthermore, a driving steam turbine is arranged between the nuclear power device and the power generation module, and the nuclear power device is sequentially connected with the driving steam turbine and the power generation module.

According to the offshore hydrogen and methanol production storage tank platform based on the combination of nuclear power and wind power, further, the methanol production module is communicated with the methanol storage tank.

According to the marine hydrogen and methanol production storage cabin platform based on the combination of nuclear power and wind power, furthermore, the power generation module and the power distribution module are arranged in a cabin below a deck of the floating platform.

According to the offshore hydrogen and methanol production storage tank platform based on the combination of nuclear power and wind power, furthermore, the floating platform is moored at an operation position through a mooring device (15).

Above-mentioned marine hydrogen manufacturing methyl alcohol storage tank platform based on nuclear power, wind-powered electricity generation combine together, further, floating platform deck top, the one side far away from nuclear power device are provided with office life building.

According to the offshore hydrogen production and methanol production storage cabin platform based on the combination of nuclear power and wind power, further, the carbon dioxide capture module is communicated with the carbon dioxide storage cabin.

According to the offshore hydrogen production and methanol production storage tank platform based on the combination of nuclear power and wind power, furthermore, the seawater desalination device is an evaporation type or reverse osmosis type desalination device.

According to the offshore hydrogen production and methanol production storage cabin platform based on combination of nuclear power and wind power, furthermore, the carbon dioxide capture module is provided with the supercharging equipment, and the carbon dioxide captured by the carbon dioxide capture module is supplied into the methanol production module through the supercharging equipment.

Nuclear energy is used as a primary clean energy source, but there are technical and regulatory limitations on onshore applications; the offshore wind power is used as another clean energy, so that the occupation of land resources is reduced, but the problems of long power transmission distance to land, large power transmission loss and unmatched power generation load and power transmission load also exist; the invention creatively provides that nuclear energy and wind energy are efficiently utilized to prepare methanol at sea, particularly near a wind field at sea, and fuel supply is provided for land, sea and air vehicles by utilizing the convenience of methanol storage, so that carbon emission reduction and carbon neutralization are realized.

The method has the advantages that the offshore nuclear energy and wind energy are utilized to prepare the methanol, the electric power generated by the nuclear energy can be efficiently utilized to form peak-valley complementation with the whole wind power grid, and the nuclear energy power generation is adopted to operate during the peak period of the power consumption of the wind power grid; in the electricity consumption valley period of the wind power grid, the electric power of the external wind power grid is transmitted to the offshore methanol preparation storage cabin platform, and the offshore methanol preparation storage cabin platform can prepare methanol by high-load operation through the external wind power grid.

Compared with a land centralized methanol plant, the platform has the advantages of distribution and small scale, and is not limited by land terrain, function division and safe distance. Meanwhile, the offshore platform is used as a floating structure, has high reproducibility, is beneficial to standardized construction and production management, can effectively reduce operation cost, and saves management cost.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a flow diagram of a floating platform operation;

FIG. 3 is a floating platform power flow diagram;

wherein: the system comprises a nuclear power device 1, a power generation module 2, a power distribution module 3, an electrolytic hydrogen production module 4, a carbon dioxide capture module 5, a methanol production module 6, a carbon dioxide storage cabin 7, a wind power grid 8, a methanol storage cabin 9, a floating platform 10, an office and living building 11, an isolated empty cabin 12, a cable 13, a transformer substation 14 and a mooring device 15.

Detailed Description

Example 1

The invention is further explained with reference to the drawings.

As shown in fig. 1, a marine hydrogen and methanol production storage tank platform based on the combination of nuclear power and wind power has a floating platform 10 floating on the sea, and the floating platform is fixed at a predetermined operation position by a mooring device 15. A nuclear power device 1 is arranged below a deck of the floating platform and at one end of the floating platform, an isolation empty cabin 12 is arranged at the position adjacent to the nuclear power device, and the nuclear power device is isolated from other equipment by the isolation empty cabin. The power generation module 2, the power distribution module 3, the methanol storage cabin 9 and the carbon dioxide storage cabin 7 are further arranged below the deck of the floating platform, and the power generation module and the power distribution module are arranged in the cabin below the deck, so that the corrosion influence of ocean salt water mist on an electrical system is reduced. The carbon dioxide storage cabin and the methanol storage cabin are arranged below the deck in parallel, so that on one hand, the space below the deck can be effectively utilized, the capacity of the platform is fully utilized to store methanol and carbon dioxide as much as possible, and on the other hand, the stability of the floating platform is facilitated. An office building 11 is arranged above the deck of the floating platform at one end of the floating platform far away from the nuclear power device.

A seawater desalination device (not shown in the figure), an electrolytic hydrogen production module 4, a carbon dioxide capture module 5 and a methanol production module 6 are arranged above the deck of the floating platform, and the modules are arranged above the deck, so that the ventilation requirements of the offshore operation platform and other series requirements are met, and the safety during offshore operation is favorably met. The seawater desalination device, the electrolytic hydrogen production module, the methanol production module and the methanol storage cabin are sequentially connected through pipelines, a branch pipeline extends out of the methanol production module to be connected with the carbon dioxide capture module, and the carbon dioxide capture module is also communicated with the carbon dioxide storage cabin.

As shown in fig. 2, after seawater is treated by the seawater desalination device, the formed fresh water enters the electrolytic hydrogen production module, and the electrolytic hydrogen production module electrolyzes the water into hydrogen and oxygen. The seawater desalination device can produce fresh water by using a mode of single or combined evaporation or reverse osmosis, fully separating water and salt in seawater, discharging the salt water to the outside of a ship, and storing the produced fresh water for later use. The electrolytic hydrogen production module decomposes water molecules into hydrogen and oxygen in an electrolytic manner (the main principle is as follows: cathode: 4H2O +4e- ═ 2H2+4OH-, anode: 4 OH-4 e- ═ O2+2H2O, and total reaction formula: 4H2O ═ 2H2+ O2). Wherein, hydrogen can be temporarily stored for later use through additionally arranging an intermediate storage tank, and can also be supplied to the ammonia production module through a supercharging device to be directly used as a raw material, and oxygen can be released into the atmosphere.

The generated hydrogen is sent to a methanol preparation module, the hydrogen and carbon dioxide react to form methanol in the methanol preparation module, the carbon dioxide is captured by a carbon dioxide capture module from the air, the captured carbon dioxide can be stored in a carbon dioxide storage cabin or can be conveyed to the methanol preparation module through a supercharger (the methanol synthesis principle is that a methanol synthesis furnace is heated by using electric energy, the hydrogen and the carbon dioxide are introduced into the methanol synthesis furnace, and the hydrogen and the carbon dioxide react to generate the methanol under the action of a catalyst).

The offshore methanol production storage cabin platform provided by the invention utilizes nuclear energy and wind energy to generate electric power to supply power to each module, so that the offshore methanol production storage cabin platform can operate. As shown in fig. 3, the nuclear power plant is connected to a driving steam turbine (not shown), the nuclear power plant converts nuclear energy into internal energy, the driving steam turbine converts the internal energy into mechanical energy, the mechanical energy drives the power generation module to convert the internal energy into electric energy, the power generation module is connected to the power distribution module, and the generated electric energy is transmitted to each module, so that the normal operation of the offshore methanol production storage tank platform is ensured. The power distribution module is further connected with a transformer substation 14 through a cable 13, the power distribution module is connected with a wind power grid on the sea or on the land through the transformer substation, and the power is supplied to each module on the offshore methanol production storage cabin platform through the wind power grid, so that the normal operation of the offshore methanol production storage cabin platform is ensured. The power distribution module provided by the invention is connected with the wind power grid through the transformer substation, and the power distribution module can also provide power for the wind power grid. The offshore hydrogen production and ammonia production storage cabin platform is combined with a wind power grid through nuclear energy to transmit power to each module. According to the invention, the wind power grid is adopted to transmit electric power, and the wind power grid is combined with nuclear power generation while sufficient electric power resources of the wind power grid are utilized, so that the problem of uneven power supply load for the platform caused by uneven power generation and power consumption of the wind power grid can be solved. The offshore methanol preparation storage cabin platform adopts electric energy as operation driving energy, the electric energy source is a nuclear power device and a wind power grid, and zero carbon emission in the whole production process is realized through 'wind power + nuclear power' methanol preparation.

Claims (10)

1. A marine hydrogen production system methyl alcohol storage tank platform based on nuclear power, wind-powered electricity generation combine together which characterized in that: the floating type offshore power generation system is characterized by comprising a floating platform (10) floating on the sea, wherein a nuclear power device (1), a power generation module (2) and a power distribution module (3) are arranged at one end of the floating platform and below a deck of the floating platform, an isolation empty cabin (12) is arranged between the power generation module (2), the power distribution module (3) and the nuclear power device, the nuclear power device is sequentially connected with the power generation module and the power distribution module through pipelines, and a carbon dioxide storage cabin (7) and a methanol storage cabin (9) are also arranged below the deck of the floating platform;

a seawater desalination device, an electrolytic hydrogen production module (4), a methanol production module (6) and a carbon dioxide capture module (5) are arranged above the deck of the floating platform, the seawater desalination device, the electrolytic hydrogen production module and the methanol production module are sequentially connected through pipelines, a branch pipeline extending out of the air nitrogen production module is connected with the carbon dioxide capture module, and the power distribution module is respectively connected with the seawater desalination device, the electrolytic hydrogen production module, the methanol production module and the carbon dioxide capture module through pipelines;

the power distribution module is connected to the wind power system (8) via a cable (13).

2. The offshore hydrogen and methanol production storage tank platform based on the combination of nuclear power and wind power as claimed in claim 1, which is characterized in that: a transformer substation (14) is arranged between the power distribution module and the wind power grid, and the power distribution module, the transformer substation and the wind power grid are sequentially connected through a cable.

3. The offshore hydrogen and methanol production storage tank platform based on the combination of nuclear power and wind power as claimed in claim 1, which is characterized in that: and a driving steam turbine is arranged between the nuclear power device and the power generation module, and the nuclear power device is sequentially connected with the driving steam turbine and the power generation module.

4. The offshore hydrogen and methanol production storage tank platform based on the combination of nuclear power and wind power as claimed in claim 1, which is characterized in that: the methanol preparation module is communicated with the methanol storage cabin.

5. The offshore hydrogen and methanol production storage tank platform based on the combination of nuclear power and wind power as claimed in claim 1, which is characterized in that: the power generation module and the power distribution module are arranged in a cabin below a deck of the floating platform.

6. The offshore hydrogen and methanol production storage tank platform based on the combination of nuclear power and wind power as claimed in claim 1, which is characterized in that: the floating platform is moored in an operating position by a mooring means (15).

7. The offshore hydrogen and methanol production storage tank platform based on the combination of nuclear power and wind power as claimed in claim 1, which is characterized in that: an office building (11) is arranged above the deck of the floating platform and on the side far away from the nuclear power device.

8. The offshore hydrogen and methanol production storage tank platform based on the combination of nuclear power and wind power as claimed in claim 1, which is characterized in that: the carbon dioxide capturing module is communicated with the carbon dioxide storage cabin.

9. The offshore hydrogen and methanol production storage tank platform based on the combination of nuclear power and wind power as claimed in claim 1, which is characterized in that: the seawater desalination device is an evaporative type or reverse osmosis type desalination device.

10. The offshore hydrogen and methanol production storage tank platform based on the combination of nuclear power and wind power as claimed in claim 1, which is characterized in that: the carbon dioxide capture module is provided with a pressurization device, and the captured carbon dioxide is supplied into the methanol production module by the carbon dioxide capture module through the pressurization device.

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