KR102685158B1 - Waste Heat Recovery System For Ship - Google Patents

Abstract

The ship's heat recovery system is launched. The heat recovery system for a ship of the present invention includes an ammonia demand station provided on a ship and supplied with ammonia as fuel; A nitrogen generator that generates nitrogen for purging to be supplied onboard the ship; A hydrogen tank provided on the ship and storing liquefied hydrogen; An ammonia generator that synthesizes ammonia by receiving nitrogen generated from the nitrogen generator and hydrogen from the hydrogen tank; And a first ammonia supply line that supplies ammonia synthesized in the ammonia generating unit to the ammonia consumer, and preheating the ammonia consumer to the operating temperature by reaction heat generated during ammonia synthesis in the ammonia generating unit. Do it as

Description

Waste heat recovery system for ship {Waste Heat Recovery System For Ship}

The present invention relates to a heat recovery system for a ship, which synthesizes ammonia from hydrogen and nitrogen on board the ship and supplies it as fuel to ammonia users, while effectively utilizing the reaction heat generated during ammonia synthesis. .

As the global warming phenomenon intensifies, efforts are being made to reduce greenhouse gas emissions around the world, and as the 1997 Kyoto Protocol, which included obligations for developed countries to reduce greenhouse gases, expires in 2020, the event held in Paris, France in December 2015 The 195 parties participating in the Paris Climate Change Accord, which was adopted at the 21st United Nations Framework Convention on Climate Change and came into effect in November 2016, are making various efforts with the goal of reducing greenhouse gases.

Along with this global trend, interest in renewable energy (or renewable energy) such as wind, solar energy, solar power, bioenergy, tidal power, and geothermal heat as a pollution-free energy that can replace fossil fuels and nuclear power is increasing, and various technologies are being developed. I'm losing.

Liquefied gases, including liquefied natural gas, can remove or reduce air pollutants during the liquefaction process, so they can be viewed as eco-friendly fuels that emit fewer air pollutants during combustion. Accordingly, the consumption of liquefied gases such as Liquefied Natural Gas (LNG) and LPG (Liquefied Petroleum Gas) has recently been rapidly increasing worldwide. Liquefied gas, which is made by liquefying gas at low temperature, has a much smaller volume than gas, so it has the advantage of increasing storage and transportation efficiency.

Liquefied natural gas (LNG) is a colorless and transparent liquid obtained by liquefying natural gas containing methane as a main component by cooling it to about -162°C, and has a volume of about 1/600 of that of natural gas. Therefore, when natural gas is liquefied and transported, it can be transported very efficiently.

Liquefied petroleum gas (LPG) has different liquefaction temperatures depending on its composition, but in the case of petroleum gas mainly containing propane, it is liquefied at a low temperature of about -42℃ at normal pressure, up to a temperature of about 45℃ at 18 bar, and 20℃ at 7 bar. It can be stored in liquid state up to ℃.

Meanwhile, conventional LPG carriers, etc., adopt a fuel supply system that uses relatively inexpensive heavy oil such as bunker C oil as propulsion fuel for ships. This heavy oil fuel supply system has the international exhaust gas emissions associated with the use of heavy oil fuel. Due to strengthened regulations, a separate low-sulfur heavy fuel fuel tank (LSHFO tank) had to be installed, and the demand for an eco-friendly fuel supply system that meets international environmental regulation standards has increased.

Recently, the application of fuel supply systems that use LPG or LNG and boil-off gas generated therefrom as propulsion fuel has been increasing in LPG or LNG carriers, and in accordance with the strengthening of international exhaust gas emission regulations, in addition to LPG or LNG carriers, general ships also use LNG. The number of ships using propulsion fuel is increasing.

However, although LNG and LPG are considered eco-friendly fuels compared to other fossil fuels previously used as ship fuels, they still produce carbon dioxide when burned, and ships that use them as fuel still emit carbon dioxide during operation.

IMO (International Maritime Organization), a UN specialized organization established to internationally unify shipping routes, traffic rules, port facilities, etc., also plans to reduce greenhouse gases by 50% in 2050 compared to 2008 and reduce greenhouse gases by 100% by 2100. % reduction (GHG Zero Emission) is proposed as the goal, and regulations in each country and region are expected to be strengthened accordingly.

According to EEDI (Energy Efficiency Design Index), a mandatory carbon dioxide reduction regulation applied by IMO to new ships, the initial EEDI announcement called for a 10% reduction in carbon dioxide emissions in 2015 based on carbon dioxide emissions from 2013 to 2015. EEDI Phase 1 was applied, and it was planned to apply Phase 3 in 2025 by strengthening and applying one step every five years. However, for LPG carriers, EEDI Phase 3 will be applied early from 2022, two years after the application of EEDI Phase 2. It is being done. As regulations on carbon dioxide emissions from ships are rapidly being strengthened, it may be difficult to achieve carbon dioxide emissions regulations in the future by using only LNG or LPG as fuel.

Accordingly, various studies are being conducted on eco-friendly marine fuels that can reduce carbon dioxide emissions, and recently, technologies for marine engines that can use ammonia as fuel along with fuels such as LNG or LPG are being researched and developed.

Ammonia (NH ₃ ) is a substance in which three hydrogens are bonded to one nitrogen. It can form strong hydrogen bonds between molecules, making it easy to liquefy. It has a boiling point of -33.34°C and a melting point of -77.73°C at normal pressure. Ammonia is easy to mass produce through the Haber-Bosch method and is evaluated to have excellent economic efficiency compared to other carbon neutral fuels. When ammonia (NH ₃ ) is synthesized using the Haber-Bosch Process, a temperature range of about 400 to 500°C occurs.

Meanwhile, ammonia is easier to store than LNG, and although it is slightly lower in SPECIFIC ENERGY and ENERGY DENSITY compared to existing HFO, it does not emit any carbon dioxide, so it is attracting attention as an eco-friendly marine fuel that can respond to the trend of strengthening international greenhouse gas emission standards. .

In addition, ammonia contains three hydrogen atoms per molecule and is easier to liquefy and store than hydrogen, so its value as a means of transporting hydrogen to use hydrogen, a representative eco-friendly fuel, as a fuel has been recognized, and various studies are being conducted.

The present invention seeks to propose a method for effectively utilizing the heat of reaction during the ammonia synthesis reaction while synthesizing ammonia on ships and supplying it as fuel.

According to one aspect of the present invention for solving the above-described problem, an ammonia demand station provided on a ship and supplied with ammonia as fuel;

A nitrogen generator that generates nitrogen for purging to be supplied onboard the ship;

A hydrogen tank provided on the ship and storing liquefied hydrogen;

An ammonia generator that synthesizes ammonia by receiving nitrogen generated from the nitrogen generator and hydrogen from the hydrogen tank; and

A first ammonia supply line that supplies ammonia synthesized in the ammonia generating unit to the ammonia demand source,

A heat recovery system for a ship is disclosed, characterized in that the ammonia demand source is preheated to an operating temperature by reaction heat generated during ammonia synthesis in the ammonia generating unit.

Preferably, an ammonia tank provided on the ship and storing ammonia; a second ammonia supply line that transfers the ammonia generated in the ammonia generating unit to the ammonia tank; And a first heat exchanger provided in the second ammonia supply line and transferring the reaction heat to the onboard heat recovery device, wherein after the operating temperature of the ammonia demand source is satisfied, the ammonia generated in the ammonia generating unit is It may be transferred to the ammonia tank through the first heat exchanger.

Preferably, it further includes an evaporator that vaporizes the liquefied hydrogen stored in the hydrogen tank and supplies it to the ammonia generating unit, wherein the ammonia generating unit contains hydrogen gas vaporized from hydrogen evaporation gas generated in the hydrogen tank or liquefied hydrogen. can be supplied.

Preferably, a first gas-liquid separator provided in the second ammonia supply line to separate gas-liquid from ammonia that has passed through the first heat exchanger; a second heat exchanger that receives the liquefied hydrogen stored in the hydrogen tank and vaporizes it; And it may further include a gas cooling line supplying the gas separated in the first gas-liquid separator to the ammonia tank through the second heat exchanger.

Preferably, it further includes a second gas-liquid separator that receives the liquefied hydrogen vaporized in the second heat exchanger and separates the gas-liquid, and the gas separated in the second gas-liquid separator is supplied to the ammonia generating unit or a hydrogen demand source in the ship. And the liquid can be transferred to the hydrogen tank.

Preferably, the ammonia generating unit includes a compressor that receives and compresses the nitrogen and hydrogen; and a reactor for synthesizing ammonia by receiving nitrogen and hydrogen compressed in the compressor. Ammonia can be produced at high temperature and pressure by the Haber-Borsh Process.

Preferably, it may further include an ammonia vaporizer that vaporizes the ammonia stored in the ammonia tank and supplies it to the ammonia demand source.

Preferably, the ammonia consumer may be a high-temperature fuel cell including a SOFC (Solid Oxide Fuel Cell) or MCFC (Molten Carbonate Fuel Cell).

In the present invention, an ammonia demand source, such as a high-temperature fuel cell that uses ammonia as fuel, is provided on a ship, and ammonia is produced and supplied as fuel by synthesizing hydrogen and nitrogen on board the ship, and the ammonia demand source is created using the reaction heat during ammonia synthesis. Preheat to operating temperature. In addition, after preheating to operating temperature, the reaction heat generated by ammonia production is recovered through a heat recovery device to produce electricity.

In this way, by producing ammonia on board to supply fuel and recovering reaction heat to generate electricity, energy efficiency can be improved and fuel consumption required for electricity production can be reduced through surplus electricity production.

In addition, when producing ammonia, by using the equipment already installed on board to generate nitrogen for purging, the utilization of the equipment can be increased and the cost of installing additional equipment can be reduced.

Figure 1 schematically shows a ship's heat recovery system according to an embodiment of the present invention.

In order to fully understand the operational advantages of the present invention and the objectives achieved by practicing the present invention, reference should be made to the accompanying drawings illustrating preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, the structure and operation of a preferred embodiment of the present invention will be described in detail with reference to the attached drawings. Here, in adding reference numerals to components in each drawing, it should be noted that identical components are indicated with the same reference numerals as much as possible, even if they are shown in different drawings.

Hereinafter, the ship in the present invention refers to all types of ships equipped with a demand source such as a fuel cell that can use ammonia as fuel, which will be described later, and representative examples include an LNG carrier, a liquid hydrogen carrier, and an LNG RV (Regasification). It includes ships with self-propulsion capabilities such as LNG FPSO (Floating Production Storage Offloading) and LNG FSRU (Floating Storage Regasification Unit), as well as offshore structures that do not have propulsion capabilities but are floating in the sea. The source of demand for batteries, etc. may be those provided for the propulsion or power generation of ships.

Figure 1 schematically shows a ship's heat recovery system according to an embodiment of the present invention.

As shown in FIG. 1, the heat recovery system of this embodiment synthesizes and supplies ammonia from nitrogen and hydrogen on board a ship equipped with an ammonia consumer (AC) that receives ammonia as fuel, and removes the high temperature generated during ammonia synthesis. It is a system that recovers reaction heat, that is, thermal energy.

This system consists of a nitrogen generator (NG) that produces nitrogen for purging to be supplied onboard the ship, a hydrogen tank that is provided on the ship and stores liquefied hydrogen, and ammonia by receiving nitrogen generated from the nitrogen generator and hydrogen from the hydrogen tank. It includes an ammonia generating unit (100) for synthesis, and supplies the ammonia synthesized in the ammonia generating unit to the ammonia demander (AC) through the first ammonia supply line (AL1), thereby dissipating the reaction heat generated during ammonia synthesis in the ammonia generating unit. It is characterized by preheating the ammonia consumer (AC) to operating temperature.

The ammonia generator 100 includes a compressor 110 that receives and compresses nitrogen and hydrogen, and a reactor 120 that synthesizes ammonia by receiving nitrogen and hydrogen compressed from the compressor, using the Haber-Bosch method (Haber-Bosch method). It may be a device that generates ammonia at high temperature and pressure through the Borsh Process.

The nitrogen generator (NG) can use a device designed to produce and supply nitrogen for purge of engine combustion chambers or fuel supply pipes, and produces nitrogen and stores it in the nitrogen storage tank (NT) to synthesize ammonia. It can be supplied to the compressor 110 along the nitrogen supply line (NL).

Hydrogen can be supplied to the compressor 110 in a gaseous state by evaporating hydrogen evaporation gas or liquefied hydrogen generated from liquefied hydrogen stored in the hydrogen tank (HT) through the hydrogen supply line (HL).

In the ammonia generator 100, nitrogen and hydrogen are supplied in gaseous form, compressed, and generate high-temperature ammonia gas through a reactor. When ammonia is synthesized by the Haber-Bosch method, ammonia gas is generated at a temperature of about 400 to 500° C., so this embodiment was designed to recover the reaction heat of such high temperature ammonia gas.

First, the high-temperature ammonia gas generated in the ammonia generator 100 is supplied to the ammonia demander to preheat the ammonia demander to the operating temperature. In this way, the ammonia consumer (AC) that receives ammonia as fuel may be, for example, a high-temperature fuel cell including a solid oxide fuel cell (SOFC) or molten carbonate fuel cell (MCFC). The ammonia gas generated in the ammonia generator is sent to the high-temperature fuel cell through the first ammonia supply line (AL1), and when the fuel cell is preheated by the ammonia gas and reaches the operating temperature, the fuel cell begins normal operation and produces power. You can. Ammonia gas supplied directly to the high-temperature fuel cell preheats the high-temperature fuel cell to operating temperature and is used as fuel for initial power production in the fuel cell. After reaching the operating temperature, hydrogen or ammonia gas can be supplied as fuel depending on the low-temperature/high-temperature fuel cell characteristics. In other words, the hydrogen consumer (HC) described later may be a fuel cell.

The ship is equipped with an ammonia tank (AT) to store ammonia, and the boil-off gas and ammonia generated from ammonia stored in the ammonia tank can be vaporized in the ammonia vaporizer 600 and supplied to ammonia demand. In addition to high-temperature fuel cells, the ammonia consumer (AC) can also be an ammonia transfer system at the terminal.

A second ammonia supply line (AL2) is connected to transfer the ammonia generated in the ammonia generation unit to the ammonia tank, and the second ammonia supply line transfers the reaction heat of the ammonia gas generated in the ammonia generation unit to the onboard heat recovery device 300. A first heat exchanger 200 that transmits heat is provided. After the ammonia demand source and the operating temperature of the high-temperature fuel cell are met, the ammonia generated in the ammonia generator can be transferred to the ammonia tank (AT) through the first heat exchanger through the second ammonia supply line.

The working fluid circulating in the heat recovery device is heated by receiving reaction heat from ammonia gas in the first heat exchanger (200) and then recovered to the heat recovery device (300), where it is used for steam generation, organic Rankine cycle, etc. Electric power can be produced from heat energy absorbed from the first heat exchanger.

Meanwhile, the system is provided with an evaporator 400 that vaporizes the liquefied hydrogen stored in the hydrogen tank and supplies it to the ammonia generator. Hydrogen gas vaporized in the evaporator may be supplied to the compressor 110 for ammonia synthesis.

A first gas-liquid separator 250 is provided in the second ammonia supply line (AL2) to separate gas-liquid from ammonia that has passed through the first heat exchanger 200. In addition, a second heat exchanger 500 is provided to receive and vaporize the liquefied hydrogen stored in the hydrogen tank, and the ammonia gas separated in the first gas-liquid separator 250 is supplied to the ammonia tank through the second heat exchanger 500. A gas cooling line (GL) is provided. The liquid separated in the first gas-liquid separator 250 can be directly supplied to the ammonia tank (LL).

This system further includes a second gas-liquid separator 550 that receives hydrogen vaporized in the second heat exchanger 500 and separates gas-liquid, and the gas separated in the second gas-liquid separator, that is, hydrogen gas, is separated from the ammonia generator ( 100) or is supplied to the hydrogen demand point (HC) on board the ship, and the liquid is transferred to the hydrogen tank (HT) and stored. Hydrogen demand sources may include low-temperature fuel cells or high-temperature fuel cells such as PEMFC (Polymer Electrolyte Membrane Fuel Cell), or terminal hydrogen transport systems.

It is obvious to those skilled in the art that the present invention is not limited to the above-mentioned embodiments, and that it can be implemented with various modifications or variations without departing from the technical gist of the present invention. It was done.

AT: Ammonia tank
AC: Ammonia demand source
NG: Nitrogen generator
HT: Hydrogen tank
100: Ammonia production unit
200: first heat exchanger
300: Heat recovery device
400: Evaporator
500: second heat exchanger

Claims (8)

Ammonia demand station provided on ships and supplied with ammonia as fuel;
A nitrogen generator that generates nitrogen for purging to be supplied onboard the ship;
A hydrogen tank provided on the ship and storing liquefied hydrogen;
An ammonia generator that synthesizes ammonia by receiving nitrogen generated from the nitrogen generator and hydrogen from the hydrogen tank; and
A first ammonia supply line that supplies ammonia synthesized in the ammonia generating unit to the ammonia demand source,
The ammonia consumer is a high-temperature fuel cell including SOFC (Solid Oxide Fuel Cell) or MCFC (Molten Carbonate Fuel Cell),
A heat recovery system for a ship, characterized in that ammonia gas is supplied from the ammonia generator to preheat the ammonia consumer to an operating temperature and used as fuel for initial power production. According to clause 1,
An ammonia tank provided on the ship and storing ammonia;
a second ammonia supply line that transfers the ammonia generated in the ammonia generating unit to the ammonia tank; and
It further includes a first heat exchanger provided in the second ammonia supply line and transferring reaction heat to the heat recovery device onboard the ship,
After the operating temperature of the ammonia demand source is met, the ammonia generated in the ammonia generating unit is transferred to the ammonia tank through the first heat exchanger. According to clause 2,
It further includes an evaporator that vaporizes the liquid hydrogen stored in the hydrogen tank and supplies it to the ammonia generator,
A heat recovery system for a ship, characterized in that hydrogen gas vaporized from hydrogen evaporation gas or liquefied hydrogen generated in the hydrogen tank is supplied to the ammonia generator. According to clause 3,
A first gas-liquid separator provided in the second ammonia supply line to separate gas-liquid from ammonia that has passed through the first heat exchanger;
a second heat exchanger that receives the liquefied hydrogen stored in the hydrogen tank and vaporizes it; and
A gas cooling line supplying the gas separated in the first gas-liquid separator to the ammonia tank through the second heat exchanger. According to clause 4,
It further includes a second gas-liquid separator that receives the liquefied hydrogen vaporized in the second heat exchanger and separates gas-liquid,
A heat recovery system for a ship, characterized in that the gas separated in the second gas-liquid separator is supplied to the ammonia generating unit or a hydrogen demand source within the ship, and the liquid is transferred to the hydrogen tank. The method of claim 5, wherein the ammonia generating unit
A compressor that receives and compresses the nitrogen and hydrogen; and
A reactor for synthesizing ammonia by receiving nitrogen and hydrogen compressed from the compressor,
A ship heat recovery system characterized in that ammonia is generated at high temperature and pressure by the Haber-Borsh Process. According to clause 6,
An ammonia vaporizer that vaporizes the ammonia stored in the ammonia tank and supplies it to the ammonia demander. delete

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