KR102528510B1 - Exhausting system for boil off gas of storage tank in ship - Google Patents

Abstract

Disclosed is the boil-off gas discharge system of the ship's storage tank. The boil-off gas discharge system of a ship storage tank according to an embodiment of the present invention is connected to a storage tank of a propulsion ship for storing liquefied gas and boil-off gas thereof, and includes a loading line for loading liquefied gas from a supply tank of a bunkering ship to a storage tank; A recovery line connected to the storage tank and recovering boil-off gas generated in the storage tank to the supply tank of the bunkering ship; a circulation line through which a heat exchange medium is circulated and supplied and provided with a first heat exchange unit; It is branched from the loading line and connected to the first heat exchange unit and the bottom of the branched point of the loading line, and nitrogen in liquid or gas state supplied through the loading line is heated by exchanging heat with the heat exchange medium by the first heat exchange unit, and then loaded. A vaporization line that flows toward the storage tank through the line; A discharge line that is connected to the recovery line and allows the evaporation gas inside the storage tank to be discharged to the outside; And a second heat exchange unit for increasing the temperature of the boil-off gas discharged by heat exchange with steam; includes.

Description

Evaporation gas discharge system of ship storage tank {EXHAUSTING SYSTEM FOR BOIL OFF GAS OF STORAGE TANK IN SHIP}

The present invention relates to an evaporation gas discharge system for a ship storage tank.

Ships using liquefied gas such as LNG (Liquefied Natural Gas) as fuel can be supplied with liquefied gas by various bunkering methods. As a bunkering method, there are a method of charging a ship from a tank lorry, a method of charging a ship from a fixed land storage tank, a method of charging a ship from a terminal, a method of charging a ship from a bunkering ship to a propulsion ship, and the like.

Here, in the case of a method of bunkering between ship-to-ship, that is, between a bunkering ship and a propulsion ship at sea, a liquefied gas loading operation is performed from the bunkering ship to the propulsion ship by a loading facility. At this time, the supply tank of the bunkering ship is connected to the storage tank of the propulsion ship through a bunkering line. The bunkering line includes a loading line and a recovery line. The bunkering ship's supply tank can be used to load liquefied gas into the propulsion ship's storage tank through a loading line and recover boil-off gas from the storage tank through a recovery line to maintain the pressure in the bunkering ship's supply tank at a certain level.

Meanwhile, the propulsion ship stores liquefied gas and its boil-off gas (BOG, Boil-Off Gas) in a storage tank. At this time, when performing periodic warm-up work and internal inspection of the storage tank, the liquefied gas remaining inside the storage tank must be evaporated and discharged to the outside.

However, when the temperature of the boil-off gas discharged to the outside through the discharge pipe is lower than -110 ° C, since it is heavier than air, a vapor cloud is created and covered on the bottom of the hull. Since boil-off gas is explosive, there is a risk that the boil-off gas cloud on the bottom of the hull may explode due to an ignition element. Please refer to Korean Patent Publication No. 10-2010-0112857 (published on October 20, 2010) as a prior art for discharging the evaporation gas inside the storage tank.

Korean Patent Publication No. 10-2010-0112857 (2010.10.20. Publication date)

An embodiment of the present invention is to provide a boil-off gas discharge system of a ship's storage tank that can safely discharge the boil-off gas inside the ship's storage tank to the outside.

According to one aspect of the present invention, it is connected to the storage tank of the propulsion line for storing liquefied gas and its boil-off gas, the loading line for loading the liquefied gas from the supply tank of the bunkering ship to the storage tank; a recovery line connected to the storage tank and recovering boil-off gas generated in the storage tank to the supply tank of the bunkering ship; a circulation line through which a heat exchange medium is circulated and supplied and provided with a first heat exchange unit; It is branched from the loading line and is connected to the first heat exchange part and the lower part of the branched point of the loading line, and liquid or gaseous nitrogen supplied through the loading line is transferred to the heat exchange medium by the first heat exchange part. A vaporization line that is heated by heat exchange with and flows toward the storage tank through the loading line; a discharge line that is connected to the recovery line and allows the evaporation gas inside the storage tank to be discharged to the outside; And a second heat exchange unit for increasing the temperature of the boil-off gas discharged by heat exchange with steam; to provide a boil-off gas discharge system of a ship storage tank including a.

According to another aspect of the present invention, it is connected to a storage tank for storing liquefied gas and its boil-off gas, a loading line for loading the liquefied gas from the supply tank of the bunkering ship to the storage tank; a recovery line connected to the storage tank and recovering boil-off gas generated in the storage tank to the supply tank of the bunkering ship; a circulation line through which a heat exchange medium is circulated and supplied and provided with a first heat exchange unit; The storage tank, the first heat exchange unit and the loading line are sequentially connected, and the liquefied gas supplied from the storage tank is vaporized through heat exchange with the heat exchange medium by the first heat exchange unit, and then passed through the loading line to the storage tank. A vaporization line that flows toward the side; a discharge line that is connected to the recovery line and allows the evaporation gas inside the storage tank to be discharged to the outside; And a second heat exchange unit for increasing the temperature of the boil-off gas discharged by heat exchange with steam; to provide a boil-off gas discharge system of a ship storage tank including a.

A third heat exchange unit may be further provided in the circulation line to increase the temperature of the heat exchange medium by performing heat exchange between the heat exchange medium passing through the first heat exchange unit and the steam.

It may further include a steam line through which the steam flows to pass through the third heat exchange part, and a temperature control line branched off from the steam line and connected to a point where the second heat exchange part and the steam line passed through the third heat exchange part. .

It further includes a temperature control valve provided in the temperature control line and a temperature measuring device provided in the discharge line to measure the temperature of the discharged boil-off gas, wherein the degree of opening of the temperature control valve is controlled based on the measured temperature value. and the steam may flow toward the second heat exchange part through the temperature control line.

The boil-off gas discharge system of the ship's storage tank according to an embodiment of the present invention can safely discharge the boil-off gas inside the ship's storage tank to the outside.

In addition, it is possible to vaporize the liquefied gas inside the storage tank by utilizing the steam of the bunkering line and the ship, and discharge it to the outside in a state where the temperature is raised.

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 a boil-off gas discharge system of a ship storage tank according to an embodiment of the present invention.
2 shows a boil-off gas discharge system of a ship storage tank according to another embodiment of the present invention.

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.

Referring to FIG. 1, the boil-off gas discharge system of the ship storage tank according to an embodiment of the present invention is connected to the storage tank 12 of the propulsion ship for storing liquefied gas and boil-off gas thereof, and the storage tank from the supply tank of the bunkering ship A loading line (L1) for loading liquefied gas into (12), a recovery line (L2) connected to the storage tank 12, and recovering boil-off gas generated in the storage tank 12 to the supply tank of the bunkering ship, , The heat exchange medium is circulated and supplied, and is branched from the circulation line (L3) provided with the first heat exchange unit 110 and the loading line (L1) to the lower part where the first heat exchange unit 110 and the loading line (L1) diverge. Connected to, liquid or gaseous nitrogen supplied through the loading line (L1) is vaporized by heat exchange with the heat exchange medium by the first heat exchange unit 110, and then stored in the storage tank 12 through the loading line (L1) The vaporization line (L4) and the recovery line (L2) are connected to the gasification line (L4) and the discharge line (L5) for discharging the evaporation gas inside the storage tank 12 to the outside, and the above-mentioned by heat exchange with steam. It includes a second heat exchanger 120 for increasing the temperature of the discharged boil-off gas.

Here, a third heat exchange unit 130 is provided in the circulation line L3 to increase the temperature of the heat exchange medium by performing heat exchange between the heat exchange medium passing through the first heat exchange unit 110 and steam.

In addition, the boil-off gas discharge system of the ship storage tank according to an embodiment of the present invention is a steam line (L6) through which steam flows to pass through the third heat exchange unit (130), and is branched from the steam line (L6) to exchange second heat. It includes a temperature control line (L7) connected to the point passing through the third heat exchange part 130 of the part 120 and the steam line (L6).

In addition, the boil-off gas discharge system of the ship storage tank according to an embodiment of the present invention measures the temperature of the boil-off gas discharged from the temperature control valve 140 provided in the temperature control line (L7) and the discharge line (L5). It includes a temperature measuring device 150. In this case, the degree of opening of the temperature control valve 140 may be adjusted based on the temperature value measured by the temperature measuring device 150 .

The boil-off gas discharge system of the ship storage tank according to an embodiment of the present invention is, for example, various liquefied fuel carriers, liquefied fuel RVs (Regasification Vessel), container ships, general merchant ships, LNG FPSOs (Floating, Production, Storage and Off-loading) ), LNG Floating Storage and Regasification Unit (FSRU), and the like. Hereinafter, each component of the boil-off gas discharge system of the ship storage tank will be described in detail.

The loading line (L1) and the recovery line (L2) are bunkering lines used for bunkering work and may remain connected to the storage tank 12 of the propulsion ship. During the bunkering operation, the loading line L1 and the recovery line L2 are connected to a supply tank (not shown) of the bunkering ship.

One side of the loading line L1 is disposed close to the inner bottom surface of the storage tank 12 of the propulsion line, and stores fluid in the storage tank 12 in a bottom filling method. And, in order to store the fluid in the storage tank 12 in the top filling method, the top filling line (L1a, Top Filling Line) branched from the loading line (L1) is provided on the inside of the storage tank 12 of the propulsion line. It is formed by extending to the side. During the bunkering operation from the bunkering ship to the propulsion ship, one or more of the loading line L1 and the top filling line L1a may be used to perform the liquefied gas loading operation.

In an embodiment of the present invention, the liquefied gas inside the storage tank 12 may be vaporized and discharged to the outside by utilizing the loading line L1 and the recovery line L2. That is, the liquefied gas remaining inside the storage tank 12 for periodic warm-up work and internal inspection of the storage tank must be generated as boil-off gas and discharged to the outside. When a significant amount of liquefied gas remains in the storage tank 12, the liquefied gas stored in the storage tank 12 is moved to another storage tank as much as possible, and then the remaining liquefied gas in the storage tank 12 is vaporized by performing , the vaporized boil-off gas can be discharged to the outside.

At this time, liquid or gaseous nitrogen is supplied through the loading line L1 in order to vaporize the remaining liquefied gas in the storage tank 12 . Hereinafter, an example in which liquid nitrogen (hereinafter referred to as liquid nitrogen (LN2)) is supplied through the loading line L1 will be described for better understanding, but gaseous nitrogen may also be supplied. In addition, when preheated nitrogen is supplied through the loading line L1, preheated nitrogen may be directly supplied to the storage tank 12 through the loading line L1. In this case, the opening/closing valve V1 disposed on the loading line L1 is in an open state.

The liquid nitrogen supplied through the loading line L1 passes through the first heat exchanger 110 through the vaporization line L4 and then flows into the storage tank 12 through the loading line L1 again. The vaporization line (L4) is branched from the loading line (L1) and is connected to the lower portion of the first heat exchange unit 110 and the branching point of the loading line (L1). At this time, the vaporization line (L4) is disposed on the loading line (L1) between the point (D1) where it diverges from the loading line (L1) and the point (D2) where the vaporization line (L4) is connected to the loading line (L1) again The on-off valve (V1) and the flow valve (V2) provided in the top filling line (L1a) are in a closed state, so liquid nitrogen flows from the loading line (L1) through the vaporization line (L4) and again through the loading line (L1). It flows into the storage tank 12.

The first heat exchange unit 110 performs heat exchange between the heat exchange medium circulated through the circulation line L3 and the aforementioned liquid nitrogen introduced through the vaporization line L4. Through this, the first heat exchange unit 110 heats and vaporizes the liquid nitrogen. In addition, the first heat exchanger 110 may vaporize the liquefied gas supplied from the storage tank 12 during ship operation and supply it as fuel to a customer (not shown). The heat exchange medium that is heat-exchanged with liquid nitrogen in the first heat exchange unit 110 may include, for example, glycol water. The liquid nitrogen introduced into the first heat exchange unit 110 through the vaporization line L4 is converted into a gaseous state after passing through the first heat exchange unit 110, and the inside of the storage tank 12 through the loading line L1. Is supplied to, converts the liquefied gas stored in the storage tank 12 into boil-off gas.

The heat exchange medium that has undergone heat exchange with liquid nitrogen in the first heat exchange unit 110 passes through the first heat exchange unit 110 and then flows to the third heat exchange unit 130 of the circulation line L3, whereby the temperature is increased by heat exchange with steam. It rises. A circulation pump P is provided between the first heat exchange unit 110 and the third heat exchange unit 130 of the circulation line L3 to circulate the heat exchange medium.

Steam flows through the steam line (L6) to pass through the third heat exchanger (130). Such steam can be generated by, for example, waste heat from waste gas discharged from a ship's boiler or gas turbine.

The evaporation gas inside the storage tank 12 flows toward the discharge line L5 communicating with the recovery line L2 through the recovery line L2 and is discharged to the outside.

The second heat exchange unit 120 provided in the discharge line (L5) increases the temperature of the boil-off gas by heat exchange with the steam described above. If the temperature of the boil-off gas discharged to the outside is lower than -110 ° C, it is heavier than air, so a cloud of boil-off gas is created and spread on the bottom of the hull, which can increase the risk of explosion. Therefore, in the embodiment of the present invention, the temperature of the boil-off gas is increased by the second heat exchanger 120 to prevent the boil-off gas cloud from being generated during external discharge.

At this time, the steam heat-exchanged with the boil-off gas described above by the second heat exchange unit 120 is supplied to the second heat exchange unit 120 through a temperature control line L7 branched from the steam line L6. The temperature control line (L7) is branched from the steam line (L6) and is connected to a point (D3) passing through the second heat exchange part 120 and the third heat exchange part 130 of the steam line (L6). In this way, the steam generated by the waste heat of the waste gas discharged from the boiler or gas turbine of the ship is supplied to the second heat exchange unit 120 and the third heat exchange unit 130 to raise the temperature of the boil-off gas and the heat exchange medium can be used effectively for

Since the temperature of the boil-off gas discharged to the outside through the second heat exchange unit 120 must be higher than at least -110 ° C, the second heat exchange unit 120 of the discharge line (L5) is provided at the point where it passed through 150 ) Based on the measured temperature value, the degree of opening of the temperature control valve 140 may be adjusted.

The temperature control valve 140 is provided at the inlet side of the second heat exchange part 120 of the temperature control line L7, and can control the amount of steam supplied to the second heat exchange part 120. For example, when the temperature value measured by the temperature measuring device 150 is lower than the set value, the degree of opening of the temperature control valve 140 increases so that a large amount of steam can be supplied to the second heat exchange unit 120 .

On the other hand, referring to Figure 2, the evaporation gas discharge system of the ship storage tank according to another embodiment of the present invention is connected to the storage tank 12 for storing liquefied gas and its evaporation gas, from the supply tank of the bunkering ship to the storage tank ( 12) a loading line (L1) for loading liquefied gas, and a recovery line (L2) connected to the storage tank 12 and recovering boil-off gas generated in the storage tank 12 to the supply tank of the bunkering ship; The heat exchange medium is circulated and supplied, and the circulation line L3 provided with the first heat exchange unit 110, the storage tank 12, the first heat exchange unit 110, and the loading line L1 are sequentially connected, and the storage tank A vaporization line (L4) for allowing the liquefied gas supplied from (12) to flow toward the storage tank (12) through the loading line (L1) after heat exchange with the heat exchange medium by the first heat exchange unit (110) and vaporization; A discharge line L5 connected to the line L2 and discharging the boil-off gas inside the storage tank 12 to the outside, and a second heat exchange unit for increasing the temperature of the boil-off gas discharged by heat exchange with steam ( 120). Hereinafter, overlapping content with FIG. 1 will be omitted as much as possible.

For example, when an abnormality occurs in the storage tank 12 during ship operation and an internal inspection of the storage tank 12 is required, the liquefied gas remaining inside the storage tank 12 is generated as boil-off gas and must be discharged to the outside. At this time, when a large amount of liquefied gas remains inside the storage tank 12, the liquefied gas inside the storage tank 12 is transferred to another storage tank as much as possible, and the remaining liquefied gas remaining in the storage tank 12 is stored in the storage tank ( It can be evaporated by vaporizing the liquefied gas remaining in 12) and re-injecting it.

To this end, the vaporization line (L4) flows toward the storage tank 12 through the loading line (L1) after the liquefied gas supplied from the storage tank 12 is vaporized by heat exchange with the heat exchange medium by the first heat exchange unit 110 The catalog storage tank 12, the first heat exchange unit 110 and the loading line L1 are sequentially connected.

Here, the liquefied gas discharge pump 14 installed inside the storage tank 12 supplies liquefied gas to the first heat exchange unit 110 through the vaporization line L4.

The first heat exchange unit 110 vaporizes the liquefied gas by performing heat exchange between the heat exchange medium circulated through the circulation line L3 circulating in the circulation line L3 and the liquefied gas introduced through the vaporization line L4.

The heat exchange unit 110 may vaporize the liquefied gas supplied from the storage tank 12 during ship operation and supply the liquefied gas as fuel to a customer (not shown).

The liquefied gas vaporized by the first heat exchanger 110 is converted into a gas component and flows back into the storage tank 12 through the loading line L1 to evaporate the remaining liquefied gas remaining in the storage tank 12. .

The evaporation gas inside the storage tank 12 flows toward the discharge line L5 communicating with the recovery line L2 through the recovery line L2 and is discharged to the outside, and as described above in FIG. 1, the second heat exchange unit 120 ), it can be discharged to the outside in a state where the temperature is raised according to the set value.

In this way, it is possible to efficiently process the remaining liquefied gas inside the storage tank 12 by using the loading line (L1) and the recovery line (L2), which are bunkering lines. It can be discharged safely to the outside. In addition, at the same time, the temperature of the heat exchange medium that exchanges heat with the fluid supplied into the storage tank 12 can be increased by utilizing the ship's steam. Through this, it can be used to vaporize the fluid supplied into the storage tank 12 and convert the remaining liquefied gas in the storage tank 12 into boil-off gas.

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.

12: storage tank 110: first heat exchange unit
120: second heat exchange unit 130: third heat exchange unit
140: temperature control valve 150: temperature measuring instrument
L1: loading line L2: recovery line
L3: circulation line L4: vaporization line
L5: discharge line L6: steam line
L7: temperature control line

Claims (5)

A loading line connected to a storage tank of a propulsion ship for storing liquefied gas and boil-off gas thereof, and loading liquefied gas from a supply tank of a bunkering ship into the storage tank;
a recovery line connected to the storage tank and recovering boil-off gas generated in the storage tank to the supply tank of the bunkering ship;
a circulation line through which a heat exchange medium is circulated and supplied and provided with a first heat exchange unit;
It is branched from the loading line and is connected to the first heat exchange part and the lower part of the branched point of the loading line, and liquid or gaseous nitrogen supplied through the loading line is transferred to the heat exchange medium by the first heat exchange part. A vaporization line that is heated by heat exchange with and flows toward the storage tank through the loading line;
a discharge line that is connected to the recovery line and allows the evaporation gas inside the storage tank to be discharged to the outside; and
Boiled gas discharge system of a ship storage tank comprising a; second heat exchange unit for increasing the temperature of the boil-off gas discharged by heat exchange with steam. A loading line connected to a storage tank for storing liquefied gas and boil-off gas thereof, and loading liquefied gas from a supply tank of a bunkering ship into the storage tank;
a recovery line connected to the storage tank and recovering boil-off gas generated in the storage tank to the supply tank of the bunkering ship;
a circulation line through which a heat exchange medium is circulated and supplied and provided with a first heat exchange unit;
The storage tank, the first heat exchange unit and the loading line are sequentially connected, and the liquefied gas supplied from the storage tank is vaporized through heat exchange with the heat exchange medium by the first heat exchange unit, and then passed through the loading line to the storage tank. A vaporization line that flows toward the side;
a discharge line that is connected to the recovery line and allows the evaporation gas inside the storage tank to be discharged to the outside; and
A second heat exchange unit for increasing the temperature of the discharged boil-off gas by heat exchange with steam; includes,
The circulation line is further provided with a third heat exchange unit for increasing the temperature of the heat exchange medium by performing heat exchange between the heat exchange medium passing through the first heat exchange unit and the steam. According to claim 1,
The evaporation gas discharge system of the ship storage tank further provided in the circulation line is a third heat exchange unit for increasing the temperature of the heat exchange medium by performing heat exchange between the heat exchange medium passing through the first heat exchange unit and the steam. According to claim 2 or 3,
A steam line through which the steam flows to pass through the third heat exchange unit;
The boil-off gas discharge system of the ship storage tank further comprising a temperature control line branched from the steam line and connected to a point passing through the second heat exchange part and the third heat exchange part of the steam line. According to claim 4,
A temperature control valve provided in the temperature control line;
Further comprising a temperature measuring device provided in the discharge line to measure the temperature of the discharged boil-off gas,
The boil-off gas discharge system of the ship storage tank, wherein the degree of opening of the temperature control valve is adjusted based on the measured temperature value, and the steam flows toward the second heat exchange part through the temperature control line.

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