KR102538535B1 - Ammonia treatment system of ship - Google Patents

Abstract

An ammonia treatment system for ships is disclosed. An ammonia treatment system for a ship according to an embodiment of the present invention includes a first storage unit and a second storage unit that store water or a neutralizing agent separated by a partition wall to dilute the ammonia component, respectively, and the first storage unit and the second storage unit. A storage tank equipped with a steam transfer means connecting parts; And flowing one or more fluids of ammonia vapor, ammonia liquid, and ammonia water generated by spraying water to ammonia gas leaked in the ship or discharged to the outside into the liquid fluid of the first storage unit to remove the ammonia component contained in the fluid. An ammonia transfer line for dilution; wherein the vapor transfer means flows the gaseous fluid inside the first storage unit into the liquid fluid stored in the second storage unit so that the ammonia component contained in the gaseous fluid is diluted do.

Description

Ammonia treatment system of ship {AMMONIA TREATMENT SYSTEM OF SHIP}

The present invention relates to an ammonia treatment system for ships.

Recently, developments have been made to utilize ammonia as an energy source for various consumers, and ships using ammonia as fuel are equipped with a system for storing and processing ammonia.

Ammonia can be stored in a pressurized state in a storage tank and can be harmful to the human body even at low concentrations. For example, if ammonia is released into the atmosphere without controlling its concentration, it can form a cloud heavier than air, which can have fatal consequences for personnel on board.

Therefore, ammonia vapor and liquid ammonia discharged to the outside from ammonia fuel tanks, engines, etc., or leaked due to malfunctioning valves, cracks in pipes, poor flange connections of equipment, etc., will be treated in accordance with the emission standards and safely discharged. There is a need.

As a prior art related to a ship that stores ammonia and uses it as fuel, please refer to Korean Patent Registration No. 10-2111503 (registered on May 11, 2020).

Korean Registered Patent No. 10-2111503 (registered on May 11, 2020)

An embodiment of the present invention is to provide an ammonia treatment system that effectively dilutes and discharges ammonia generated in a ship.

According to one aspect of the present invention, a vapor connecting the first storage unit and the second storage unit includes a first storage unit and a second storage unit respectively storing water or a neutralizing agent separated by a partition wall to dilute the ammonia component. A storage tank equipped with a moving means; and flowing one or more fluids of ammonia vapor, ammonia liquid, and ammonia water generated by spraying water to ammonia gas leaked in the ship or discharged to the outside into the liquid fluid of the first storage unit, and ammonia contained in the fluid An ammonia transfer line for diluting the components, wherein the vapor transfer means flows the gaseous fluid inside the first storage unit into the liquid fluid stored in the second storage unit, and is contained in the gaseous fluid A ship's ammonia treatment system may be provided to dilute the ammonia component.

The bulkhead may be provided vertically, and the vapor moving means may include a dilution line connecting an empty space above the surface of the water in the first storage unit to the water in the second storage unit.

The bulkhead is provided horizontally and forms one or more through-holes so that the gaseous fluid of the first storage unit flows toward the second storage unit disposed above the first storage unit, and the vapor moving means comprises the through-holes. It includes a guide member installed on the surface of the partition wall on the side of the second storage part and a bubble cap disposed in a form to cover and embrace the guide member and having a slot formed on the periphery, wherein part or all of the bubble cap is It is provided to be immersed in the liquid fluid stored in the second storage unit, and the gaseous fluid of the first storage unit, which has passed through the through hole and moved to the inside of the bubble cap along the guide member, passes through the slot to the first storage unit. The ammonia component contained in the gaseous fluid may be diluted by being dissolved in the liquid fluid stored in the second storage unit.

The bulkhead is provided horizontally and forms one or more through-holes so that the gaseous fluid of the first storage unit flows toward the second storage unit disposed above the first storage unit, and the vapor moving means comprises the through-holes. and a valve tray which is movably inserted up and down and is provided so that a portion protruding toward the second storage portion around the partition wall is locked by the liquid fluid stored in the second storage portion, wherein the valve tray is pushed up. When the pressure of the first storage unit and the pressure of the second storage unit pressing the valve tray are the same, the valve tray is maintained covering the through hole, and the gaseous fluid of the first storage unit flows inside the valve tray. When flowing through and pushing up the valve tray, the gaseous fluid may flow through slots formed in the valve tray and dissolve in the liquid fluid stored in the second storage unit.

The valve tray is disposed toward the second storage unit with the partition wall as the center, includes a cover portion covering the through hole, a support plate supporting the cover portion, and a vertical extension from the support plate to be inserted into the through hole. A guide body having a slot, and a hook formed at the lower end of the guide body so that the gaseous fluid of the first storage unit enters the inside of the guide body and the valve tray is raised to be caught around the through-hole on the side of the first storage unit of the partition wall. May include chin.

A gaseous discharge line for discharging gaseous fluid inside the second storage unit toward the vent mast may be further included.

It is connected to one of the first storage unit and the second storage unit, and at least one of water, seawater, and a neutralizing agent is used to adjust the concentration of the ammonia component contained in the liquid fluid stored in the first storage unit and the second storage unit. It may further include a concentration control line to supply.

It may further include a liquid discharge line for discharging the liquid fluid inside the first storage unit and the second storage unit.

A vacuum breaker or check valve is provided in the liquid phase discharge line, and the vacuum breaker or check valve may be disposed below a position where the storage tank and the liquid phase discharge line are connected.

The ship's ammonia treatment system according to an embodiment of the present invention can effectively dilute and discharge ammonia generated in the ship.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 shows an ammonia treatment system for a ship according to an embodiment of the present invention.
FIG. 2 shows an ammonia treatment system of a ship having a partition wall dividing the first storage part and the second storage part of the storage tank shown in FIG. 1 horizontally and having a steam moving means accordingly.
3 is a perspective view of the bubble cap shown in FIG. 2;
FIG. 4 is a cross-sectional view of the bubble cap shown in FIG. 3 and shows how gaseous fluid inside the first storage unit of the storage tank moves to the second storage unit.
5 is a valve tray as a steam moving means so that a partition wall dividing the first storage part and the second storage part of the storage tank shown in FIG. 1 is provided horizontally, and the gaseous fluid inside the first storage part moves to the second storage part. It is shown as a cross-sectional view.
FIG. 6 shows a state in which a check valve is provided to prevent a vacuum from being generated while discharging the liquid fluid stored in the first storage unit and the second storage unit shown in FIG. 1 overboard.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments introduced below are provided as examples to sufficiently convey the spirit of the present invention to those skilled in the art. The present invention is not limited to the embodiments described below and may be embodied in other forms. In order to clearly explain the present invention, parts irrelevant to the description are omitted from the drawings, and in the drawings, the width, length, thickness, etc. of components may be exaggerated for convenience. Like reference numbers indicate like elements throughout the specification.

1 shows an ammonia treatment system for a ship according to an embodiment of the present invention.

Referring to FIG. 1, the ship's ammonia treatment system 100 according to an embodiment of the present invention includes a first storage unit 111 for storing water or a neutralizing agent that dilutes the ammonia component separated by a partition wall 101, and A storage tank 110 including a second storage unit 112 and provided with a steam moving means connecting the first storage unit 111 and the second storage unit 112, and leaking inside the ship or discharged to the outside An ammonia transfer line for diluting the ammonia component contained in the fluid by flowing one or more fluids of ammonia vapor, ammonia liquid, and ammonia water generated by spraying water on ammonia gas into the liquid fluid of the first storage unit 111 ( 120).

Here, the vapor moving means flows the gaseous fluid inside the first storage unit 111 into the liquid fluid stored in the second storage unit 112, so that the ammonia component contained in the gaseous fluid is diluted.

Hereinafter, each component of the ship's ammonia treatment system 100 will be described in detail.

As shown in FIG. 1, the storage tank 110 includes a first storage unit 111 and a second storage unit 112 respectively storing water for diluting the ammonia component or a neutralizing agent.

Here, the first storage unit 111 and the second storage unit 112 may be separated by a partition wall 101 provided vertically.

The first storage unit 111 and the second storage unit 112 may store water for diluting the ammonia component or a neutralizing agent. For example, water may be stored in the first storage unit 111 and a neutralizing agent may be stored in the second storage unit 112 . Hereinafter, for convenience of description, an example in which water is stored in both the first storage unit 111 and the second storage unit 112 will be described.

The first storage unit 111 is connected to the ammonia transfer line 120, and the first storage unit 111 and the second storage unit 112 are connected by a vapor moving means.

The ammonia transfer line 120 transfers one or more fluids of ammonia water generated by spraying water to ammonia vapor, ammonia liquid, and ammonia gas leaked in the ship or discharged to the outside into the liquid fluid of the first storage unit 111. It flows to dilute the ammonia component contained in the fluid.

Specifically, ammonia vapor and liquid ammonia discharged to the outside from the ammonia fuel tank 122, engine (not shown), etc., or leaked due to valve malfunction, cracks in pipes, poor flange connection parts of equipment, etc., are transferred to ammonia. It may flow to the first storage unit 111 through the line 120.

The vapor transfer means flows the gaseous fluid inside the first storage unit 111 into the liquid fluid stored in the second storage unit 112, so that the ammonia component contained in the gaseous fluid is diluted.

At this time, the gaseous fluid inside the first storage unit 111 includes gas that is not dissolved (absorbed) in the liquid fluid stored in the first storage unit 111 among the ammonia gas transported by the ammonia transfer line 120. can

In addition, in the gaseous fluid inside the first storage unit 111, evaporation gas generated from a mixed solution in which ammonia gas transported by the ammonia transfer line 120 is dissolved in the liquid fluid stored in the first storage unit 111 is added. can include

Such a steam moving means may include a dilution line 130 connecting an empty space above the surface of the water of the first storage unit 111 and the inside of the water of the second storage unit 112 . The gaseous fluid present in the empty space above the water surface of the first storage unit 111 flows into the water of the second storage unit 112 through the dilution line 130, and the ammonia component contained in the gaseous fluid It can be dissolved in the water filled in the second storage unit 112.

2 is a view of an ammonia treatment system of a ship having a partition wall dividing the first storage part and the second storage part of the storage tank shown in FIG. It is a perspective view of the bubble cap shown in 2. And, FIG. 4 is a cross-sectional view of the bubble cap shown in FIG. 3, showing how the gaseous fluid inside the first storage unit of the storage tank moves to the second storage unit.

As shown in FIGS. 2 to 4, the above-described partition wall 101 is horizontally separated to separate the first storage part 111 below and the second storage part 112 above the first storage part 111. can be provided.

At this time, the partition wall 101 forms one or more through holes H1 so that the gaseous fluid in the first storage unit 111 flows toward the second storage unit 112 .

In addition, the steam moving means is disposed in a form of covering and subsuming the guide member 141 installed on the side of the second storage unit 112 of the partition wall 101 according to the through hole H1, and the guide member 141, , a bubble cap 143 having a slot H2 formed at the periphery.

Here, part or all of the bubble cap 143 may be provided to be submerged in liquid fluid stored in the second storage unit 112 . As an example, FIG. 2 shows a partially submerged bubble cap 143, and FIGS. 3 and 4 show a fully submerged bubble cap 143.

The fluid in the gaseous phase of the first storage unit 111, which has moved to the inside of the bubble cap 143 along the guide member 141 through the through hole H1, passes through the slot H2 around the bubble cap 143. The solution is dissolved in the liquid fluid stored in the second storage unit 112, and the ammonia component contained in the gaseous fluid is diluted.

The guide member 141 is, for example, provided in a cylindrical shape to fit the through hole H1 and may be vertically installed on the surface of the partition wall 101 toward the second storage unit 112, and the first storage unit introduced through the through hole H1. The gaseous fluid of (111) naturally flows into the bubble cap 143 along the passage formed by the guide member 141.

As shown in FIGS. 3 and 4 , the bubble cap 143 is provided in a 'U' shape, for example, and is disposed to cover and submerge the guide member 141 . Accordingly, the exit portion of the guide member 141 faces the inner surface of the head portion 143a of the bubble cap 143, and the circumferential portion of the guide member 141 is surrounded by the peripheral portion 143b of the bubble cap 143. It comes face to face with the inner world of the surroundings.

The inner diameter of the guide member 141 may be equal to or larger than the diameter formed by the through hole H1, and since the guide member 141 is vertically disposed on the surface of the partition wall 101 on the side of the second storage unit 112, The water stored in the second storage unit 112 may be filled up to a certain height in the space between the inner surface of the peripheral portion 143b of the bubble cap 143 and the guide member 141 .

In addition, the empty space on the water surface of the first storage unit 111, the passage of the guide member 141 connected thereto through the through hole H1, and the upper space of the bubble cap 143 are formed as empty spaces through which gas can flow. It can be.

The bubble cap 143 naturally surrounds the bubble cap 143 after the fluid in the gaseous phase of the first storage unit 111 introduced through the through hole H1 hits the inner surface of the head portion 143a of the bubble cap 143. (143b) It may be coupled to maintain a certain distance from the guide member 141 so as to move along the inner surface.

At this time, the gaseous fluid of the first storage unit 111 flowing into the bubble cap 143 naturally flows toward the peripheral portion 143b of the bubble cap 143 and passes through the peripheral slot H2.

Since the water in the second storage unit 112 is filled up to a certain level inside the bubble cap 143, at least a part of the gaseous fluid in the first storage unit 111 dissolves in water while passing through the slot H2. It can be, and bubbles may occur in this process.

5 is a valve tray as a steam moving means so that a partition wall dividing the first storage part and the second storage part of the storage tank shown in FIG. 1 is provided horizontally, and the gaseous fluid inside the first storage part moves to the second storage part. It is shown as a cross-sectional view.

As shown in FIG. 5, the partition wall 101 is provided horizontally so that the gaseous fluid in the first storage unit 111 flows toward the second storage unit 112 disposed above the first storage unit 111. One or more through holes H1 are formed.

Here, the steam moving means is inserted into the through-hole H1 to be movable up and down, and a portion protruding toward the second storage unit 112 around the partition wall 101 is the liquid fluid stored in the second storage unit 112. It may include a valve tray 190 provided to be locked by.

Specifically, the valve tray 190 is disposed on the side of the second storage unit 112 with the partition wall 101 as the center, and includes a cover unit 192 covering the through hole H1 and a support plate supporting the cover unit 192. 194, the guide body 196 extending vertically from the support plate 194 and inserted into the through hole H1 and having the slot H3 formed therein, and the gaseous fluid of the first storage part 111 is passed through the guide body ( 196) When the valve tray 190 is raised after entering the inside, the locking jaw 198 formed at the lower end of the guide body 196 is set so as to be caught around the through hole H1 on the side of the first storage part 111 of the partition wall 101 include

Referring to (a) of FIG. 5 , when the pressure of the first storage unit 111 pushing up the valve tray 190 and the pressure of the second storage unit 112 pressing the valve tray 190 are the same, the valve tray 190 is maintained while covering the through hole H1. That is, when the pressure of the gaseous fluid inside the first storage unit 111 pushing up the valve tray 190 is the same as the pressure of the liquid fluid in the second storage unit 112 pressing the valve tray 190, the valve The tray 190 is in a state of covering the through hole H1.

Referring to (b) of FIG. 5 , when the gaseous fluid of the first storage unit 111 flows through the inside of the valve tray 190 and pushes up the valve tray 190, the gaseous phase of the first storage unit 111 The fluid flows through the slot H3 formed on the upper side of the valve tray 190 and dissolves in the liquid fluid stored in the second storage unit 112 . In this case, the pressure of the gaseous fluid inside the first storage unit 111 pushing up the valve tray 190 is greater than the pressure of the liquid fluid in the second storage unit 112 pressing the valve tray 190 . When the gaseous fluid pressure inside the first reservoir 111 is gradually reduced, the guide body 196 of the valve tray 190 gradually descends along the through hole H1 and pushes the valve tray 190 up. When the pressure of the gaseous fluid inside the first reservoir 111 reaches the same state as the pressure of the liquid fluid in the second reservoir 112 pressing the valve tray 190, the cover portion 192 of the valve tray 190 is in a state of covering the through hole H1.

Meanwhile, as shown in FIG. 2, the gaseous fluid inside the second storage unit 112 may be discharged toward the vent mast through the gaseous discharge line 150 connected to the second storage unit 112. there is.

The gaseous fluid inside the second storage unit 112 may include boil-off gas generated from a mixed fluid in which the gaseous fluid flowing from the first storage unit 111 is dissolved in water stored in the second storage unit 112. .

In addition, the gaseous fluid inside the second storage unit 112 may include gaseous fluid (gas) flowing from the first storage unit 111 that is not dissolved in water stored in the second storage unit 112 .

The concentration meter 155 provided in the second storage unit 112 measures the concentration of the ammonia component contained in the gaseous fluid inside the second storage unit 112, and when the ammonia concentration meets the external emission standards, Gas-phase fluid inside the second storage unit 112 may be discharged toward the vent mast through the gas-phase discharge line 150 by opening the valve 157 .

In order to adjust the concentration of the ammonia component contained in the liquid fluid stored in the first storage unit 111 and the second storage unit 112, the ship's ammonia treatment system 100 supplies one or more of water, seawater, and a neutralizing agent. It may include a concentration control line 160 that does.

The concentration control line 160 may be connected to one or more of the first storage unit 111 and the second storage unit 112 .

For example, the concentration control line 160 may be connected to a ballast tank 165 to supply ballast water to one or more of the first storage unit 111 and the second storage unit 112 .

In addition, the concentration control line 160 may supply seawater to one or more of the first storage unit 111 and the second storage unit 112, and in this case, although not shown, various foreign substances and microorganisms present in the seawater A seawater treatment device for removing impurities may be provided.

The flow rate of the fluid supplied to one or more of the first storage unit 111 and the second storage unit 112 through the concentration control line 160 is stored in the first storage unit 111 and the second storage unit 112. It can be adjusted according to the concentration of the ammonia component contained in the liquid fluid. To this end, means (not shown) for measuring the concentration of the ammonia component contained in the liquid fluid stored in the first storage unit 111 and the second storage unit 112 may be provided.

As described above, in the embodiment of the present invention, the first storage unit 111 and the second storage unit 112 are separated by one partition wall 101, so that the first storage unit 111 and the second storage unit are separated. Although it has been described as an example that the ammonia component of the fluid is dissolved and sequentially diluted by the water stored in (112), it is not limited thereto, and two or more partition walls may be provided so that the ammonia component is sequentially diluted through more storage units.

Referring to FIG. 6 , the ship's ammonia treatment system 100 may include a liquid discharge line 170 for discharging liquid fluid inside the first storage unit 111 and the second storage unit 112 .

The first storage unit 111 and the second storage unit 112 flow the liquid fluid to the liquid discharge line 170 through the vertical pipe 175 .

At this time, the liquid phase fluid falls vertically through the vertical pipe 175 to the position where the storage units 111 and 112 and the liquid phase discharge line 170 are connected, that is, the uppermost part 170a of the liquid phase discharge line 170. The fluid in the first storage unit 111 and the second storage unit 112 is voluntarily discharged by the vacuum generated at the top of the 170.

Also, a vacuum breaker 180 or a check valve may be provided in the liquid phase discharge line 170, and the vacuum breaker 180 or the check valve may be disposed at a lower position 170b than the uppermost part 170a. Through this, outside air (air) can flow into the liquid phase discharge line 170, thereby preventing pipe damage caused by the aforementioned vacuum.

Liquid fluid inside the first storage unit 111 and the second storage unit 112 by the vacuum breaker 180 or check valve provided at a position 170b lower than the uppermost part 170a of the liquid discharge line 170 is sucked in so that smooth discharge can be achieved.

Through this, the liquid fluid inside the first storage unit 111 and the second storage unit 112 can be effectively discharged without a separate power source.

In the above, specific embodiments have been illustrated and described. However, the present invention is not limited to the above-described embodiments, and those skilled in the art can make various changes without departing from the gist of the technical idea set forth in the claims below. You will be able to.

101: bulkhead 110: storage tank
111: first storage unit 112: second storage unit
120: ammonia transfer line 130: dilution line
141: guide member 143: bubble cap
150: gaseous discharge line 160: concentration control line
170: liquid discharge line 175: vertical pipe
180: vacuum breaker

Claims (12)

A storage tank comprising a first storage part and a second storage part for storing water or a neutralizing agent separated by a partition wall to dilute ammonia components, respectively, and provided with a vapor transfer means connecting the first storage part and the second storage part; and
Ammonia component contained in the fluid by flowing one or more fluids of ammonia vapor, ammonia liquid, and ammonia water generated by spraying water to ammonia gas leaked from inside the ship or discharged to the outside into the liquid fluid of the first storage unit Including an ammonia transfer line for diluting,
The steam moving means,
The gaseous fluid inside the first storage unit flows into the liquid fluid stored in the second storage unit so that the ammonia component contained in the gaseous fluid is diluted.
The barrier rib is provided horizontally and forms one or more through holes so that the gaseous fluid of the first storage unit flows toward the second storage unit disposed above the first storage unit,
The steam moving means,
A guide member installed on the side of the second storage part of the partition wall to fit the through hole;
It is disposed in a form to cover and embrace the guide member, and includes a bubble cap having a slot formed on the periphery,
Part or all of the bubble cap is provided to be submerged in the liquid fluid stored in the second storage unit,
The gaseous fluid of the first storage unit passing through the through hole and moving along the guide member to the inside of the bubble cap passes through the slot and dissolves in the liquid fluid stored in the second storage unit, thereby dissolving the gaseous fluid Ship's ammonia treatment system in which the ammonia component contained in is diluted. delete delete A storage tank comprising a first storage part and a second storage part for storing water or a neutralizing agent separated by a partition wall to dilute ammonia components, respectively, and provided with a vapor transfer means connecting the first storage part and the second storage part; and
Ammonia component contained in the fluid by flowing one or more fluids of ammonia vapor, ammonia liquid, and ammonia water generated by spraying water to ammonia gas leaked from inside the ship or discharged to the outside into the liquid fluid of the first storage unit Including an ammonia transfer line for diluting,
The steam moving means,
The gaseous fluid inside the first storage unit flows into the liquid fluid stored in the second storage unit so that the ammonia component contained in the gaseous fluid is diluted.
The barrier rib is provided horizontally and forms one or more through holes so that the gaseous fluid of the first storage unit flows toward the second storage unit disposed above the first storage unit,
The steam moving means,
A valve tray inserted into the through hole so as to be movable up and down, and a portion protruding toward the second storage part centering on the partition wall is locked by liquid fluid stored in the second storage part,
When the pressure of the first storage unit pushing up the valve tray and the pressure of the second storage unit pressing the valve tray are the same, the valve tray remains covering the through hole,
When the gaseous fluid of the first storage part flows through the inside of the valve tray and pushes the valve tray up, the gaseous fluid flows through the slot formed in the valve tray and dissolves in the liquid fluid stored in the second storage part. ship's ammonia treatment system. According to claim 4,
The valve tray
a cover part disposed toward the second storage part with respect to the partition wall and covering the through hole;
a support plate supporting the cover;
A guide body extending vertically from the support plate and inserted into the through hole, and having the slot formed in the periphery;
Ship's ammonia including a locking jaw formed at the lower end of the guide body to be caught around the through-hole on the first storage side of the bulkhead when the gaseous fluid of the first storage unit enters the inside of the guide body and the valve tray is raised processing system. delete delete A storage tank comprising a first storage part and a second storage part for storing water or a neutralizing agent separated by a partition wall to dilute ammonia components, respectively, and provided with a vapor transfer means connecting the first storage part and the second storage part; and
Ammonia component contained in the fluid by flowing one or more fluids of ammonia vapor, ammonia liquid, and ammonia water generated by spraying water to ammonia gas leaked from inside the ship or discharged to the outside into the liquid fluid of the first storage unit Including an ammonia transfer line for diluting,
Further comprising a liquid discharge line for discharging the liquid fluid inside the first storage unit and the second storage unit,
The steam moving means,
The ship's ammonia treatment system for flowing the gaseous fluid inside the first storage unit into the liquid fluid stored in the second storage unit so that the ammonia component contained in the gaseous fluid is diluted. According to claim 8,
A vacuum breaker or check valve is provided in the liquid discharge line, and the vacuum breaker or check valve is disposed below a position where the storage tank and the liquid discharge line are connected. According to claim 8,
The bulkhead is provided vertically,
The steam transfer unit includes a dilution line connecting an empty space above the water surface of the first storage unit and an inside of the water of the second storage unit. The method of claim 1, 4 or 8,
The ship's ammonia treatment system further comprising a gaseous discharge line for discharging the gaseous fluid inside the second storage unit toward the vent mast. The method of claim 1, 4 or 8,
It is connected to one of the first storage unit and the second storage unit, and at least one of water, seawater, and a neutralizing agent is used to adjust the concentration of the ammonia component contained in the liquid fluid stored in the first storage unit and the second storage unit. Ship's ammonia treatment system further comprising a supply concentration control line.

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