KR20210105853A - Marine terminal for manufacturing energy using fresh water supplied from bunkering vessel - Google Patents

Abstract

The present invention relates to a marine terminal for production of energy, and more specifically, to a marine terminal, wherein the marine terminal receives fresh water from a bunkering vessel and a marine plant installed at sea and the fresh water undergoes electrolysis so as to produce energy such as hydrogen or ammonia. The marine terminal for production of energy in accordance with the present invention comprises: a marine plant; a fresh water tank; a fresh water pipeline; an electrolysis means; a hydrogen tank; a pipeline; and a plurality of floating power generation means. The marine terminal is installed at sea. The fresh water tank is mounted on the marine plant to accommodate fresh water. The fresh water pipeline may be connected to the marine plant and connected to the bunkering vessel so as to receive fresh water from the bunkering vessel and store the received fresh water in the fresh water tank. The electrolysis means is mounted on the marine plant to electrolyze the fresh water accommodated in the fresh water tank. The hydrogen tank is mounted on the marine plant to store hydrogen generated by being decomposed in the fresh water by means of the electrolysis means. The pipeline may be connected to the marine plant and connected to the bunkering vessel so that the hydrogen accommodated in the hydrogen tank can be sent to the bunkering vessel. The plurality of floating power generation means are installed around the marine plant to produce electricity to be supplied to the marine plant. In accordance with the present invention, the marine plant may receive electricity from the plurality of floating power generation means installed at sea. Because the efficiency of wind power generators installed at sea is higher than those installed on land, the marine plant may receive more electrical energy than onshore plants.

Description

Marine terminal for manufacturing energy using fresh water supplied from bunkering vessel}

The present invention relates to an offshore terminal for energy production, and more particularly, to an offshore terminal capable of producing energy such as hydrogen or ammonia by receiving freshwater from a bunkering ship and electrolyzing the freshwater in an offshore plant installed in the sea.

The use of hydrogen is encouraged as an eco-friendly policy to suppress carbon emission. In order to use hydrogen, hydrogen must be produced, and there are green hydrogen, blue hydrogen and gray hydrogen depending on the production method. Blue hydrogen and gray hydrogen generate carbon dioxide when producing hydrogen, so there is a limit in suppressing carbon generation.

For this reason, green hydrogen is suitable to suppress carbon generation, and green hydrogen is produced by water electrolysis to decompose water. At this time, electricity is used to produce hydrogen by electrolysis of water, so hydrogen is produced by water electrolysis using eco-friendly renewable energy.

Conventionally, it is possible to produce only a small amount of hydrogen by supplying a small amount of electrical energy produced by one power generation means provided on one side of an offshore wind generator installed in the sea or a solar power generator’s own platform to the electrolysis electrolyzer, It was difficult to secure economic feasibility.

In addition, since the seawater supplied to the electrolysis cell contains chlorine and various foreign substances, it was impossible to directly electrolyze seawater. electrolyzed.

Application No. 10-2010-0088494 (filed on September 09, 2010) Application No. 10-2012-0101867 (application date 2012.09.14) Application No. 10-2007-0065568 (application date 2007.06.29) Application No. 10-2010-0132616 (application date 2010.12.22) Application No. 10-2019-0053138 (application date 2019.05.07) Application No. 10-2010-0099590 (application date 2010.10.13) Application No. 10-2010-00117606 (application date 2010.11.24)

As in the conventional method, when hydrogen is produced using seawater containing chlorine and various foreign substances, a seawater desalination process is required.

In addition, in the case of conventional seawater filtering, there is a problem that the maintenance cost increases because the filter in the membrane must be periodically replaced.

In addition, the conventional offshore wind power generator or photovoltaic generator installed in the sea is provided with only one power generation means on one side of its own platform, so that only a small amount of electric energy is produced. Therefore, the use of electric power equipment that requires electric energy at sea had to be used very limitedly. For this reason, there was a problem in that the commercialization of an offshore energy terminal plant that produces hydrogen or ammonia was delayed.

The present invention is intended to solve the above problems. An object of the present invention is to provide an offshore terminal for energy production that can produce fuel that can be used as energy such as hydrogen or ammonia by using freshwater from an offshore plant installed in the sea without a seawater desalination process.

An offshore terminal for energy production according to the present invention includes an offshore plant, a freshwater tank, a freshwater pipeline, an electrolysis means, a hydrogen tank, and a plurality of floating power generation means. The offshore plant is installed offshore. The fresh water tank is mounted on the offshore plant to accommodate fresh water. The freshwater pipeline may be connected to the offshore plant by receiving the fresh water from the bunkering vessel and storing it in the freshwater tank. The electrolysis means is mounted on the offshore plant to electrolyze the fresh water accommodated in the fresh water tank. The hydrogen tank is mounted on the offshore plant to store the hydrogen generated by being decomposed in the fresh water by the electrolysis means. The plurality of floating power generation means are installed around the offshore plant to produce electricity for supplying the offshore plant.

In addition, it is preferable that the offshore terminal for energy production further includes a pipeline that is connected to the offshore plant and can be connected to the bunkering ship so that the hydrogen accommodated in the hydrogen tank can be sent to the bunkering ship.

In addition, the offshore terminal for energy production preferably further includes a nitrogen tank, an ammonia production means, and an ammonia tank. The nitrogen tank is mounted on the offshore plant to store nitrogen. The ammonia production means is mounted on the offshore plant to produce ammonia using the hydrogen stored in the hydrogen tank and the nitrogen stored in the nitrogen tank. The ammonia tank is mounted on the offshore plant to store the ammonia produced by the ammonia production means. In this case, the pipeline transports the ammonia stored in the ammonia tank to the bunkering vessel.

In addition, the offshore terminal for energy production is installed in the vicinity of the offshore plant so that the bunkering ship can dock by absorbing the collision with the bunkering ship, and the freshwater pipe connected from the offshore plant to the bunkering ship It is preferable to further include a floating berthing plant on which the line and the pipeline are mounted.

In addition, it is preferable that the above-mentioned offshore terminal for energy production further includes an oxygen tank and an oxygen pipeline. The oxygen tank is mounted on the offshore plant to store the oxygen produced by the electrolysis means. The oxygen pipeline may be connected to the offshore plant so as to send oxygen stored in the oxygen tank to the bunkering vessel and connected to the bunkering vessel.

According to the present invention, an offshore plant can receive electricity from a plurality of floating power generation means installed in the sea. Since the efficiency of wind power generators is higher at sea than on land, offshore plants can receive more electrical energy than on land.

In addition, according to the present invention, hydrogen and ammonia are produced by receiving fresh water from a ship and electrolyzing the fresh water at sea. Therefore, it is possible to increase the production of hydrogen and ammonia because the vast amount of electrical energy input in the seawater desalination process is not used.

In addition, according to the present invention, hydrogen and ammonia produced in an offshore plant are transferred to a ship through a pipeline. Therefore, economic feasibility can be secured.

1 is an embodiment of an offshore terminal for energy production receiving fresh water from a bunkering vessel according to the present invention;
Figure 2 is a partially enlarged view of Figure 1;
3 is a view viewed from another angle of the embodiment of FIG. 1;
4 is an embodiment of an offshore terminal for energy production receiving fresh water from a bunkering vessel using a berthing plant;
5 and 6 are views viewed from another angle of FIG. 4 .

An embodiment of an offshore terminal for energy production according to the present invention will be described with reference to FIGS. 1 to 3 .

An embodiment of an offshore terminal for energy production according to the present invention includes an offshore plant 11, a freshwater tank 13, an electrolysis means 15, a hydrogen tank 17, a pipeline 19, A plurality of floating power generation means 21, fresh water pipeline 23, nitrogen tank 25, ammonia production means 27, ammonia tank 29, oxygen tank 31 and oxygen pipe It includes a line 35 , a nitrogen generating means 35 , and an eyepiece plant 37 .

The offshore plant 11 is installed in the sea. In this embodiment, the leg of the offshore plant 11 is fixed to the sea floor, and the upper surface is exposed on the sea, so that various devices can be installed on the upper surface. However, the offshore plant 11 may be installed in a floating manner.

The fresh water tank 13 is mounted on the offshore plant 11 to accommodate fresh water.

The freshwater pipeline 23 may be connected to the offshore plant 11 so as to receive fresh water from the bunkering vessel 5 and store it in the freshwater tank 13 to be connected to the bunkering vessel 5 .

The electrolysis means 15 is mounted on the offshore plant 11 to electrolyze the fresh water accommodated in the fresh water tank 13 . When the electrolysis means 15 electrolyzes fresh water, hydrogen and oxygen are generated.

The hydrogen tank 17 is mounted on the offshore plant 11 to store hydrogen generated by electrolysis of fresh water in the electrolysis means 15 .

The pipeline 19 is connected to the offshore plant 11 so as to transport the hydrogen contained in the hydrogen tank 17 or the ammonia contained in the ammonia tank 29 to be described below to the bunker ship 5 . ) can be connected. Therefore, when hydrogen or ammonia is stored in the hydrogen tank 17 or the ammonia tank 29 , the hydrogen or ammonia can be transferred to the bunkering vessel 5 through the pipeline 19 .

A plurality of floating power generation means 21 is installed in the sea around the offshore plant 11 to produce electricity to supply electricity to the offshore plant (11). The power generation means 21 may be implemented in various forms, such as a wind power generator, a solar power generator, a wave power generator, a tidal current generator, an ocean current generator, etc., and is implemented in a floating type so that a plurality of them are installed around the offshore plant 11 . The floating power generation means 21 may be fixed at sea with the mooring cable 1, and the power cable 3 is the power generation means ( 21) to the offshore plant (11). The power cable 3 may be connected to the offshore plant 11 from the power generation means 21 to the sea. When the electricity produced by the floating power generation means 21 is supplied to the offshore plant 11, the electrolysis means 15, ammonia production means 27, nitrogen generating means 35, etc. mounted on the offshore plant 11 are can be driven

The nitrogen tank 25 is mounted on the offshore plant 11 to store nitrogen. Nitrogen may be supplied from the bunkering vessel 5 through a nitrogen pipeline (not shown) or supplied from the nitrogen generating means 35 below.

The ammonia production means 27 is mounted on the offshore plant 11 to produce ammonia by using the hydrogen stored in the hydrogen tank 17 and the nitrogen stored in the nitrogen tank 25 . Of course, the ammonia production means 27 is operated with electricity produced by the floating power generation means 21 to produce ammonia.

The ammonia tank 29 is mounted on the offshore plant 11 to store the ammonia produced by the ammonia production means 27 .

The oxygen tank 31 is mounted on the offshore plant 11 to store the oxygen produced by the electrolysis means 15 .

The oxygen pipeline 33 is connected to the offshore plant 11 so as to send the oxygen stored in the oxygen tank 31 to the bunkering vessel 5 , and may be connected to the bunkering vessel 5 .

The nitrogen generating means 35 is mounted on the offshore plant 11 to collect nitrogen in the air and store it in the nitrogen tank 25 .

In the electrolysis means 15 of this embodiment, fresh water may be electrolyzed to send hydrogen to the bunkering vessel 5 , or hydrogen may be generated into ammonia to send ammonia to the bunkering vessel 5 . When hydrogen is directly sent to the bunkering vessel 5, the nitrogen tank 25, ammonia production means 27, ammonia tank 29, and nitrogen generating means 35 for generating ammonia are not required and can be omitted. .

In order to operate this embodiment, first, fresh water is stored in the fresh water tank 13 . At this time, fresh water is supplied from the bunkering vessel (5) through the fresh water pipeline (23). At this time, when the bunkering vessel 5 is docked with the offshore plant 11 , one end of the freshwater pipeline 23 is connected to the bunkering vessel 5 to receive fresh water from the bunkering vessel 5 .

On the other hand, a plurality of floating power generation means 21 is mounted on the sea around the offshore plant (11). The floating power generation means 21 is fixed to the sea by the mooring cable 1 , and the electricity produced by the floating power generation means 21 is supplied to the offshore plant 11 through the power cable 3 . Since a plurality of floating power generation means 21 are installed, a sufficient amount of electrical energy can be supplied to the offshore plant 11 . The electric energy supplied to the offshore plant 11 operates the electrolysis means 15 , the ammonia production means 27 , or the nitrogen generating means 35 .

When fresh water is stored in the fresh water tank 13, the electrolysis means 15 operates to electrolyze the fresh water. When the electrolysis means 15 electrolyzes fresh water, hydrogen and oxygen are generated. In the conventional case, seawater is desalinated and electrolyzed, but in this embodiment, it is not necessary to desalinate the seawater, so hydrogen and oxygen can be easily produced. Hydrogen produced by the electrolysis means 15 is stored in the hydrogen tank 17 , and oxygen is stored in the oxygen tank 31 .

Oxygen stored in the oxygen tank 31 is transferred to the bunkering vessel 5 through an oxygen pipeline 33 , and hydrogen stored in the hydrogen tank 17 is transferred to the bunkering vessel 5 through the pipeline 19 . . The transported hydrogen and oxygen can be utilized as an energy source.

When hydrogen is directly transferred to the bunkering vessel 5, components for producing ammonia are not required, but components for producing ammonia are required to convert the produced hydrogen into ammonia and transport ammonia to land. are needed That is, the nitrogen tank 25, the ammonia production means 27, the ammonia tank 29 and the nitrogen generating means 35 are required.

In this case, first, nitrogen in the air is collected using the nitrogen generating means 35 and stored in the nitrogen tank 25 . Of course, when nitrogen is supplied from the bunkering vessel 5, the nitrogen generating means 35 is not required.

And the ammonia production means 27 uses the nitrogen stored in the nitrogen tank 25 and the hydrogen stored in the hydrogen tank 17 to make ammonia and store it in the ammonia tank 29 . Then, the ammonia stored in the ammonia tank 29 is supplied to the bunkering vessel 5 through the pipeline 19 .

4 to 6 are another embodiment of an offshore terminal for energy production according to the present invention.

In the case of FIGS. 1 to 3, the bunkering ship 5 is docked directly on the offshore plant 11, but in this case, the bunkering ship 5 and the offshore plant 11 collide with the offshore plant 11. An impact may be applied to the offshore plant 11. . In order to prevent this, the embodiment of FIGS. 4 to 6 further includes an eyepiece plant 37 .

The berthing plant 37 is installed around the offshore plant 11 so that the bunkering vessel 5 can dock by absorbing the collision with the buckling vessel 5 . In this case, of course, the pipeline 19 , the freshwater pipeline 23 , the oxygen pipeline 33 , etc. may be mounted on the berthing plant 37 and connected to the bunkering vessel 5 .

In the case of this embodiment, the berthing plant 37 is formed in a floating type and is fixed to the sea by the mooring cable 1 .

On the other hand, in the case of the above embodiment, the hydrogen produced by the electrolysis means in the offshore plant was transferred to the bunkering vessel. However, after storing hydrogen in an offshore plant, a hydrogen fuel power plant, a hydrogen gas turbine power plant, a hydrogen internal combustion engine power plant, a hydrogen thermal power plant, etc. may be installed in the offshore plant to generate power in the offshore plant if necessary.

1: mooring cable 3: power cable
5: Bunkering vessel 11: Offshore plant
13: fresh water tank 15: electrolysis means
17: hydrogen tank 19: pipeline
21: floating power generation means 23: freshwater pipeline
25: nitrogen tank 27: ammonia production means
29: ammonia tank 31: oxygen tank
33: oxygen pipeline 35: nitrogen generating means
37: berthing plant

Claims (5)

Offshore plants installed in the sea;
A fresh water tank mounted on the offshore plant to receive fresh water;
a freshwater pipeline which is connected to the offshore plant to receive the fresh water from the bunkering vessel and store it in the freshwater tank and which can be connected to the bunkering vessel;
an electrolysis means mounted on the offshore plant to electrolyze the fresh water accommodated in the fresh water tank;
a hydrogen tank mounted on the offshore plant to store hydrogen generated by decomposition in the fresh water by the electrolysis means;
Offshore terminal for energy production, characterized in that it comprises a plurality of floating power generation means installed in the periphery of the offshore plant to produce electricity for supply to the offshore plant. According to claim 1,
The offshore terminal for energy production, characterized in that it further comprises a pipeline that is connected to the offshore plant so as to send the hydrogen accommodated in the hydrogen tank to the bunkering vessel, which can be connected to the bunkering vessel. 3. The method of claim 2,
A nitrogen tank mounted on the offshore plant to store nitrogen;
Ammonia production means mounted on the offshore plant to produce ammonia using the hydrogen stored in the hydrogen tank and the nitrogen stored in the nitrogen tank;
Further comprising an ammonia tank mounted on the offshore plant to store the ammonia produced by the ammonia production means,
The pipeline is an offshore terminal for energy production, characterized in that the ammonia stored in the ammonia tank is transferred to the bunkering vessel. 4. The method of claim 3,
It is installed around the offshore plant to absorb the collision with the bunkering vessel so that the bunkering vessel can dock, and the freshwater pipeline connected from the offshore plant to the bunkering vessel and the floating type in which the pipeline is mounted Offshore terminal for energy production, characterized in that it further comprises a berthing plant. 5. The method according to any one of claims 1 to 4,
an oxygen tank mounted on the offshore plant to store the oxygen produced by the electrolysis means;
The offshore terminal for energy production, characterized in that it further comprises an oxygen pipeline that is connected to the offshore plant and can be connected to the bunkering vessel so that the oxygen stored in the oxygen tank can be sent to the bunkering vessel.

Images