KR20170067512A - BOG Treatment System - Google Patents

Abstract

Disclosed is an evaporative gas processing system for re-liquefying evaporative gas generated in a storage tank.
The evaporation gas treatment system may further include: a compressor for compressing the evaporated gas discharged from the storage tank; Liquefaction means for re-liquefying the evaporated gas compressed by the compressor; A circulation control valve branched from a downstream end of the compressor and installed on a line joined to a front end of the compressor; And a cooler provided on a line branching from a downstream end of the compressor and joined to a front end of the compressor, wherein the compressor is designed to compress a fluid at room temperature.

Description

[0001] BOG TREATMENT SYSTEM [0002]

The present invention relates to an evaporative gas processing system, and more particularly, to an evaporative gas processing system for re-liquefying evaporative gas generated inside a storage tank.

In recent years, consumption of liquefied gas such as Liquefied Natural Gas (LNG) has been rapidly increasing worldwide. The liquefied gas obtained by liquefying the gas at a low temperature has an advantage of being able to increase the storage and transport efficiency because the volume becomes very small as compared with the gas. In addition, liquefied natural gas, including liquefied natural gas, can be removed as an eco-friendly fuel with less air pollutant emissions during combustion because air pollutants can be removed or reduced during the liquefaction process.

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

However, since the liquefaction temperature of natural gas is a cryogenic temperature of -162 ° C at normal pressure, liquefied natural gas is sensitive to temperature changes and is easily evaporated. As a result, the storage tank storing the liquefied natural gas is subjected to heat insulation, but the external heat is continuously transferred to the storage tank. Therefore, in the transportation of liquefied natural gas, the liquefied natural gas is naturally vaporized continuously in the storage tank, -Off Gas, BOG) occurs. This also applies to other low temperature liquefied gases such as ethane.

Evaporation gas is a kind of loss and is an important issue in transport efficiency. Further, when the evaporation gas accumulates in the storage tank, the internal pressure of the tank may rise excessively, and there is a risk that the tank may be damaged. Accordingly, various methods for treating the evaporative gas generated in the storage tank have been studied. Recently, a method of re-liquefying the evaporated gas and returning it to the storage tank for treating the evaporated gas, a method of returning the evaporated gas to the storage tank And a method of using it as an energy source of a consuming place.

1 is a schematic diagram of a conventional evaporative gas treatment system.

1, a conventional evaporative gas treatment system includes a mixer 160, a compressor 110, a recondenser 120, a pump 130, a vaporizer 140, and a circulation control valve 150 .

The mixer 160 of the conventional evaporative gas treatment system injects the liquefied gas discharged from the storage tank 100 by the spray pump 171 to lower the temperature of the evaporated gas discharged from the storage tank 100. The evaporated gas cooled in the mixer 160 after being discharged from the storage tank 100 is compressed by the compressor 110 and then partly sent to the fuel consumer and the other part is sent to the recondenser 120.

The re-condenser 120 of the conventional evaporative gas treatment system is operated to remove the evaporation gas that has been discharged from the storage tank 100 and then passed through the mixer 160 and the compressor 110 and the evaporation gas from the storage tank 100 through the transfer pump 172, And the evaporation gas is re-liquefied. Some of the liquefied gas re-liquefied in the recondenser 120 is compressed by the pump 130, vaporized by the vaporizer 140 and sent onshore, and the rest is sent to the storage tank 100.

The circulation control valve 150 is maintained in a closed state when the flow rate of the evaporation gas discharged from the storage tank 100 is suitable for the capacity of the compressor 110 and the amount of the evaporation gas discharged from the storage tank 100 Is smaller than a certain level with respect to the capacity of the compressor (110).

When the circulation control valve 150 is opened, some of the evaporated gas compressed by the compressor 110 is circulated to the circulation control valve 150 until the evaporation gas of the proper capacity is supplied to the compressor 110. The evaporated gas that has passed through the circulation control valve 150 is merged with the evaporated gas discharged from the storage tank 100 and then sent to the compressor 110 via the mixer 160.

With the conventional evaporative gas treatment system, since the low-temperature compressor 110 designed to compress only the low-temperature evaporation gas is used, the evaporator gas must be cooled by the mixer 160 to maintain the inlet temperature of the compressor 110 at a low temperature And there is a problem that the amount of evaporable gas that can be processed is reduced by the amount of the liquefied gas injected to cool the evaporated gas in the mixer 160. [

According to the conventional evaporative gas treatment system, when the amount of the evaporative gas discharged from the storage tank 100 is larger than the amount of the evaporative gas re-condensed in the recondenser 120, A part of the evaporated gas flows into the storage tank 100, which may cause the internal pressure of the storage tank 100 to increase more rapidly.

The present invention has been proposed in order to solve the above problems, and relates to a vapor gas processing system using a room-temperature compressor capable of compressing a vapor gas at room temperature instead of a low-temperature compressor.

According to an aspect of the present invention, there is provided an evaporative gas processing system for re-liquefying an evaporative gas generated in a storage tank, the system comprising: a compressor for compressing evaporative gas discharged from the storage tank; Liquefaction means for re-liquefying the evaporated gas compressed by the compressor; A circulation control valve branched from a downstream end of the compressor and installed on a line joined to a front end of the compressor; And a cooler provided on a line branching from a downstream end of the compressor and joined to a front end of the compressor, wherein the compressor is designed to compress a fluid at room temperature.

The evaporation gas treatment system includes a pump for compressing the liquefied gas re-liquefied by the liquefaction means; And a vaporizer for vaporizing the liquefied gas compressed by the pump.

The re-liquefying means may be a recondenser, and the recondenser may re-liquefy the evaporated gas compressed by the compressor by mixing with the liquefied gas discharged from the storage tank.

According to another aspect of the present invention, there is provided an evaporative gas treatment method for re-liquefying an evaporative gas generated in a storage tank, comprising: 1) compressing evaporative gas discharged from the storage tank directly by a compressor; 2) a part of the evaporated gas compressed in the step 1) is sent to the fuel consumer and the remaining part is re-liquefied; 3) a part of the liquefied gas re-liquefied in the step 2) And the remaining part is returned to the storage tank.

4) when the amount of evaporated gas discharged from the storage tank is less than a certain level as compared with the capacity of the compressor, 4) a part of the evaporated gas compressed by the compressor can be branched and then cooled; and 5) The cooled evaporated gas may be combined with the evaporated gas discharged from the storage tank and then sent to the compressor. 6) Repeat the steps 4) and 5) until a flow rate of evaporative gas is supplied to the compressor can do.

The fuel consumer may be at least one of a boiler, a gas engine, and a gas combustion device.

According to the evaporation gas processing system of the present invention, since a room-temperature compressor is used in place of the low-temperature compressor, there is no need to provide a mixer for cooling the evaporation gas at the upstream side of the compressor. Therefore, since the amount of evaporated gas to be supplied is not reduced by the amount of liquefied gas injected in order to cool the evaporated gas in the mixer, more evaporation gas can be re-liquefied, which is efficient.

Further, according to the evaporation gas processing system of the present invention, when the amount of the evaporation gas supplied to the compressor by the mixer is small, the liquefied gas is not supplied into the loop where the evaporation gas is circulated. Even when the amount of the evaporated gas discharged from the storage tank is large, the probability of the evaporated gas flowing into the storage tank is significantly lowered.

1 is a schematic diagram of a conventional evaporative gas treatment system.
2 is a schematic diagram of a vaporized gas processing system of a preferred embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The evaporative gas treatment system of the present invention can be applied to various applications such as a ship equipped with an engine using natural gas as fuel and a ship including a liquefied gas storage tank. In addition, the following examples can be modified in various forms, and the scope of the present invention is not limited to the following examples.

2 is a schematic diagram of a vaporized gas processing system of a preferred embodiment of the present invention.

2, the evaporative gas processing system of the present embodiment includes a compressor 110, a recondenser 120, a pump 130, a vaporizer 140, a circulation control valve 150, and a cooler 180.

The compressor 110 of the present embodiment is designed to compress a fluid at room temperature and compresses the evaporated gas discharged from the storage tank 100 and sends it to the recondenser 120. The compressor 110 is installed between the storage tank 100 and the recondenser 120 in order to supply the evaporated gas in the storage tank 100 to the recondenser 120. [

The recondenser 120 of this embodiment mixes the evaporated gas compressed by the compressor 110 after being discharged from the storage tank 100 with the liquefied gas discharged from the storage tank 100 by the transfer pump 172 And liquefied. In the present embodiment, the recondenser has been described as an example of means for re-liquefying the evaporation gas. However, the present invention is not limited thereto. Hereinafter, means for re-liquefying the evaporation gas will be referred to as " re-liquefying means ".

The liquefied gas re-liquefied by the recondenser 120 is compressed by the pump 130, vaporized by the vaporizer 140, and then supplied to the land demand site, and excess liquefied gas exceeding the required amount at the land demand site is stored And returned to the tank 100.

The reason why the evaporated gas discharged from the storage tank 100 is directly compressed and then sent to a demand site by the recondenser 120 after being compressed and vaporized without being sent to a demand site on land, This is because the installation cost of the pump 130 for compressing the liquefied gas is much lower and the consumed power is significantly lower than that of the compressor for the compressor.

The circulation control valve 150 of the present embodiment is installed on a line L1 branched from the rear end of the compressor 110 and joined to the front end of the compressor 110 so that the amount of the evaporation gas discharged from the storage tank 100 When the amount of the evaporative gas discharged from the storage tank 100 is less than a certain level with respect to the capacity of the compressor 110, it is opened.

The cooler 180 of this embodiment is installed on a line L1 branched from the rear end of the compressor 110 and joined to the front end of the compressor 110. [ 2 shows a case where the cooler 180 is installed at the downstream of the circulation control valve 150. The cooler 180 may be installed at the upstream side of the circulation control valve 150. [ The cooler 180 of the present embodiment serves to lower the temperature of the evaporated gas that is compressed by the compressor 110 and increases not only in pressure but also in temperature.

Since the present embodiment includes the compressor 110 designed to compress the fluid at room temperature, it is not necessary to lower the temperature of the evaporated gas discharged from the storage tank 100 and then send it to the compressor 110. However, when the circulation control valve 150 is opened, since the evaporation gas is circulated through the compressor 110, the circulation control valve 150, and the cooler 180, the evaporative gas processing system of this embodiment includes the cooler 180 The temperature is continuously increased by the compressor (110).

The fluid flow in the evaporative gas treatment system of this embodiment is as follows. First, the case where the amount of the evaporated gas discharged from the storage tank 100 is appropriate to the capacity of the compressor 110 and the circulation control valve 150 is closed will be described.

The evaporated gas discharged from the storage tank 100 is compressed by the compressor 110 and then partly sent to the fuel consumer and surplus evaporated gas exceeding the required amount at the fuel consumer is sent to the recondenser 120. The fuel consumer may be at least one of a boiler, a gas engine, and a gas combustion unit (GCU).

The evaporated gas that has passed through the compressor 110 and then sent to the recondenser 120 is mixed with the liquefied gas discharged from the storage tank 100 by the transfer pump 172 and re-liquefied. The liquefied gas condensed by the recondenser 120 is compressed by the compressor 110 and is vaporized by the vaporizer 140 and then sent to the land demand site and excess liquefied gas exceeding the required amount at the land demand site is stored in the storage tank 100).

Next, the case where the amount of the evaporated gas discharged from the storage tank 100 becomes equal to or less than the capacity of the compressor 110 and the circulation control valve 150 is opened will be described.

The evaporated gas discharged from the storage tank 100 is compressed by the compressor 110 and then partly sent to the fuel consumer or the recondenser 120 and the remaining part is sent to the circulation control valve 150. The evaporated gas sent to the circulation control valve 150 is cooled by the cooler 180 and is cooled down. Thereafter, the evaporated gas is merged with the evaporated gas discharged from the storage tank 100 and sent back to the compressor 110. The evaporated gas combined with the evaporated gas discharged from the storage tank 100 and then sent back to the compressor 110 is again sent to the fuel consumer or the recondenser 120 and the remaining part is sent to the circulation control valve 150 Loses.

The loop connecting the compressor 110, the circulation control valve 150, and the cooler 180 is circulated until the appropriate amount of evaporative gas is supplied to the compressor 110 in the manner described above , The circulation control valve 150 is closed when a sufficient amount of evaporative gas is supplied to the compressor 110.

On the other hand, the evaporated gas that has been compressed by the compressor 110 and then sent to the recondenser 120 is mixed with the liquefied gas discharged from the storage tank 100 by the transfer pump 172 and re-liquefied. The liquefied gas condensed by the recondenser 120 is compressed by the compressor 110 and is vaporized by the vaporizer 140 and then sent to the land demand site and excess liquefied gas exceeding the required amount at the land demand site is stored in the storage tank 100).

The vaporizing gas processing system of the present embodiment does not include the mixer 160 and thus does not reduce the amount of vaporized gas and reduces the possibility that the evaporated gas circulating in the loop flows into the storage tank 100 .

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention. It is.

100: Storage tank 110: Compressor
120: Re-condenser 130: Pump
140: Carburetor 150: Circulation control valve
160: Mixer 171: Spray pump
172: feed pump 180: cooler

Claims (6)

An evaporative gas treatment system for re-liquefying an evaporative gas generated in a storage tank,
A compressor for compressing the evaporated gas discharged from the storage tank;
Liquefaction means for re-liquefying the evaporated gas compressed by the compressor;
A circulation control valve branched from a downstream end of the compressor and installed on a line joined to a front end of the compressor; And
And a cooler installed on a line branching from a downstream end of the compressor and joined to a front end of the compressor,
Wherein the compressor is designed to compress a fluid at room temperature. The method according to claim 1,
A pump for compressing the liquefied gas re-liquefied by the liquefaction means; And
A vaporizer for vaporizing the liquefied gas compressed by the pump;
Further comprising: The method according to claim 1 or 2,
The liquefaction means is a recondenser,
Wherein the recondenser mixes the evaporated gas compressed by the compressor with the liquefied gas discharged from the storage tank to re-liquefy the evaporated gas. A method for treating an evaporative gas, which re-liquefies the evaporative gas generated in the storage tank,
1) compressing the evaporated gas discharged from the storage tank directly by a compressor,
2) a part of the evaporated gas compressed in the step 1) is sent to the fuel consumer, the remaining part is re-liquefied,
3) A method of treating an evaporative gas according to the above 2), wherein a part of the liquefied gas re-liquefied is vaporized after compression and sent to a demand site on the ground, and a part of the liquefied gas is returned to the storage tank. The method of claim 4,
When the amount of the evaporative gas discharged from the storage tank is less than a predetermined level with respect to the capacity of the compressor,
4) A part of the evaporated gas compressed by the compressor is branched and cooled,
5) The evaporated gas cooled in the step 4) is combined with the evaporated gas discharged from the storage tank and sent to the compressor again,
6) repeating the steps 4) and 5) until a suitable amount of evaporating gas is supplied to the compressor. The method according to claim 4 or 5,
Wherein the fuel consumer is at least one of a boiler, a gas engine, and a gas combustion device.

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