KR20190082484A - Treatment system of boil-off gas - Google Patents

Abstract

According to the present invention, a boil off gas treatment system includes: a supply line connecting a demand source with a storage tank; a compressor provided on the supply line, pressurizing boil off gas in the storage tank, and transmitting the same to the demand source side; and a turbocharger using exhaust gas discharged from an engine and pressurizing inhalation fluid supplied to the engine, wherein the turbocharger can use energy left after pressurizing the inhalation fluid as power of driving the compressor.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

The present invention relates to an evaporative gas treatment system for treating an evaporative gas generated in a storage tank.

Generally, two- or four-stroke diesel engines used in ships operate in a variety of temperature conditions or climates. Therefore, it should be possible to operate under all temperature conditions from summer to winter, from polar to tropical. This temperature change acts as a cause of changes in Specific Fuel Oil Consumption (SFOC), amount of exhaust gas and temperature (exhaust gas amount & temperature). The combustion air intake system of such a diesel engine will be described as follows.

Conventionally, the combustion air intake system of a diesel engine includes a suction line that provides a path for the combustion air of the outside air or engine room to be supplied to the intake manifold of the diesel engine through a compressor of a turbocharger, The exhaust gas exhausted from the exhaust manifold of the engine is exhausted to the outside through the turbine of the turbocharger along the exhaust line. In such diesel engines, the lower the temperature of the combustion air, the lower the SFOC and the better the fuel economy.

Patent Document 1: Korean Patent Laid-Open Publication No. 10-2012-0007642 (2012.02.14)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a vaporized gas processing system for improving fuel supply performance.

According to an aspect of the present invention, there is provided a supply line connecting a storage tank and a customer; A compressor provided in the supply line to pressurize the evaporation gas in the storage tank and send it to a customer; And a turbocharger which pressurizes a suction fluid supplied to the engine by using exhaust gas discharged from the engine, wherein the turbocharger presses the suction fluid and uses the remaining energy as power for driving the compressor.

The turbocharger includes a turbine through which the exhaust gas passes and a compressor through which the intake fluid passes, and the compressor can be powered from the compressor through the power transmission portion.

Wherein the turbocharger includes a first turbocharger and a second turbocharger provided on both sides of the engine, the compressor being connected to the first turbocharger using a first power transmission unit, And can be connected using the second power transmission portion.

A supply line connecting the storage tank and the customer; A compressor provided in the supply line to pressurize the evaporation gas in the storage tank and send it to the engine; And a turbocharger which pressurizes the intake fluid supplied to the engine by using exhaust gas discharged from the engine, wherein the turbocharger presses the intake fluid and uses the remaining energy as a power for driving the compressor .

The turbocharger includes a turbine through which the exhaust gas passes and a compressor through which the intake fluid passes, and the compressor can be directly connected to the compressor.

The evaporative gas processing system according to the present invention can utilize surplus energy generated in driving the turbocharger for boosting the evaporation gas. The turbocharger presses the suction fluid supplied by using the exhaust gas generated from the engine or the customer and uses the remaining energy for boosting the evaporation gas.

1 shows a vaporized gas processing system according to a first embodiment of the present invention.
Fig. 2 shows a vaporized gas processing system according to a second embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments described below are provided by way of example so that those skilled in the art will be able to fully understand the spirit of the present invention. 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 not related to the description are omitted from the drawings, and the width, length, thickness, etc. of the components may be exaggerated for convenience. Like reference numerals designate like elements throughout the specification.

1 shows a vaporized gas processing system according to a first embodiment of the present invention. Referring to the drawings, the evaporative gas treatment system according to the first embodiment includes supply lines 20 and 40 connecting the storage tank 10 and the consumer 50, supply lines 20 and 40, And a turbocharger 70 for pressurizing the suction fluid supplied to the engine 60 by using the exhaust gas discharged from the engine 60 And the turbocharger 70 can pressurize the suction fluid and use the remaining energy as power for driving the compressor 30. [

The storage tank 10 is used to store cryogenic liquefied gas such as Liquefied Natural Gas (LNG), Liquefied Petroleum Gas (LPG), and Dimethyl Ether (DME) . In other words, the storage tank 10 may be a carrier for transporting liquefied gas such as an LNG carrier, an LNG RV (regasification vessel) carrier, an LPG carrier, or an ethylene carrier, or a floating storage regasification unit (FSRU) Offloading, and BMPP (Barge Mounted Power Plant) for the storage and production of liquefied gas. The storage tank 10 may be applied not only to marine equipment but also to land equipment for storing liquefied gas.

The first supply line 20 and the second supply line 40 connect the storage tank 10 and the consumer 50 and use the compressor 30 to pressurize the evaporation gas in the storage tank 10 50). At this time, the supply lines 20 and 40 may be connected to the inside of the storage tank 10 at the inlet side end, and the outlet side end may be connected to the demand source 50 via the supply lines 20 and 40. The supply lines 20 and 40 may be provided with a compressor 30 having a plurality of compressors (not shown) so that the evaporation gas can be processed according to the conditions required by the engine.

The customer 50 may be an engine for power generation, or an engine for generating other power. The consumer 50 is supplied with the evaporated gas pressurized by the compressor 30 to obtain the driving force. The engine 60 may be supplied with fuel gas such as liquefied natural gas and vaporized gas stored in the storage tank 10 to generate propulsive force of the ship or generate power for power generation such as internal equipment of the ship.

As described above, the engine 60 is composed of an ME-GI engine or an X-DF engine capable of generating an output with a relatively high-pressure fuel gas in accordance with the required fuel gas, and the demander 50 is composed of a relatively low- And a DFDE engine capable of generating an output to the engine. However, the present invention is not limited thereto, and it should be equally understood that various numbers of engines and various kinds of engines are used.

The turbocharger 70 is provided for assisting the combustion of the engine 60 used in the ship. The turbocharger 70 is a turbocharger that utilizes the high pressure and the designed exhaust gas force generated after the explosion stroke of the engine 60, It is possible to drive the charger 70 (turbocharger) and compress the suction fluid by the force to supply it to the combustion chamber of the engine 60.

On the other hand, the turbocharger 70 can pressurize the suction fluid and use the remaining energy as power for driving the compressor 30. The turbocharger 70 includes turbines 71 and 73 through which the exhaust gas passes and compressors 72 and 74 through which the intake fluid passes and the compressor 30 is connected to the compressors 72 and 72 through the power transmitting part 90, 74, < / RTI > The turbocharger 70 includes a first turbine 71 and a first compressor 72 disposed on the right side of the compressor 30, a second turbine 73 and a second compressor 74 disposed on the left side of the compressor 30, And the compressor 30 is connected to the first turbocharger including the first turbine 71 and the first compressor 72 using the first power transmission unit 91 and the second turbine 73 and the second turbine 73, And the second turbocharger including the second compressor 74 may be connected using the second power transmission portion 92. [

The first exhaust gas 81 and the second exhaust gas 82 generate a driving force for operating the first compressor 72 while passing through the first turbine 71 and the first compressor 72 uses this energy So that the first suction fluid 83 can be pressurized to the second suction fluid 84 state. The energy difference between the first exhaust gas 81 and the second exhaust gas 82 may be greater than the energy difference between the third exhaust gas 85 and the fourth exhaust gas 86. In this case, the energy remaining in driving the first compressor (72) in the first turbine (71) can be used as energy to pressurize the compressor (30). Likewise, the energy generated in the second turbine 73 presses the second compressor 74, and the remaining energy can be used to pressurize the compressor 30.

The power transmission unit 90 includes a first power transmission unit 91 and a second power transmission unit 92. The power transmission unit 90 includes the turbines 71 and 73 and the compressors 72 and 74, And supplies the energy generated by the turbocharger 70, which includes the compressor 30, to the compressor 30.

Accordingly, in the present invention, the energy of the exhaust gas generated in the engine 60 can be used for suctioning the fluid from the engine 60 and simultaneously used for boosting the evaporation gas using the compressor 30. [

The evaporation gas processing system according to the second embodiment of the present invention is provided in the supply lines 200 and 400 connecting the storage tank 100 and the demander 500 and the supply lines 200 and 400 so as to pressurize the evaporation gas in the storage tank 100 And a turbocharger 700 for pressurizing the intake fluid supplied to the engine 600 by using the exhaust gas discharged from the engine 500. The turbocharger 700 includes a turbocharger 700, Can pressurize the suction fluid and use the remaining energy as a driving force for driving the compressor 300.

The storage tank 100 is used to store cryogenic liquefied gas such as liquefied natural gas (LNG), liquefied petroleum gas (LPG), and dimethyl ether (DME) . That is, the storage tank 100 may be a carrier for transporting liquefied gas such as an LNG carrier, an LNG RV (regasification vessel) carrier, an LPG carrier, or an ethylene carrier, or a carrier for transporting liquefied gas such as a floating storage regasification unit (FSRU) Offloading, and BMPP (Barge Mounted Power Plant) for the storage and production of liquefied gas. The storage tank 100 may also be applied to offshore installations as well as offshore installations for storing liquefied gases.

The first supply line 200 and the second supply line 400 connect the storage tank 100 and the customer 500 and use the compressor 300 to pressurize the evaporation gas in the storage tank 100 500). At this time, the supply lines 200 and 400 may be connected to the inside of the storage tank 100 at the inlet end, and the outlet end may be connected to the demander 500 via the supply lines 200 and 400. The supply lines 200 and 400 may be provided with a compressor 300 having a plurality of compressors (not shown) so that the evaporation gas can be processed according to the conditions required by the engine.

The customer 500 may be an engine for generating power or an engine for generating other power. The customer 500 can receive the driving force by supplying the evaporated gas pressurized by the compressor 300. The customer 500 can receive fuel gas such as liquefied natural gas and vaporized gas stored in the storage tank 100 to generate propulsive force of the ship or generate electric power for generating electricity such as internal equipment of the ship.

The turbocharger 700 includes a turbine 710 through which the exhaust gas passes and a compressor 720 through which the suction fluid passes and the compressor 300 supplies power from the compressor 720 through the power transmitting portion 900 Can receive. At this time, the compressor 300 may be directly connected to the compressor 720 for efficient power transmission.

The turbocharger 700 can pressurize the suction fluid and use the remaining energy as power for driving the compressor 300. [ In detail, the first exhaust gas 810 and the second exhaust gas 820 generate a driving force for operating the compressor 720 while passing through the turbine 710, and the compressor 720 uses the energy to generate the driving force 1 sucking fluid 830 to the state of the second sucking fluid 840, and the surplus energy remaining at this time can be used as a driving force for driving the compressor 300.

As described above, according to the second embodiment, the demander 500 can raise the evaporation gas (BOG) by itself, and can be used for forming and supplying the gas pressure (5 to 8 bar) required by the customer 500.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, You will understand. Accordingly, the true scope of the invention should be determined only by the appended claims.

10: Storage tank 20: First supply line
30: compressor 40: second supply line
50: customer 60: engine
70: Turbocharger 71: First turbine
72: first compressor 73: second turbine
74: second compressor 81: first exhaust gas
82: second exhaust gas 83: first intake fluid
84: second suction fluid 85: third exhaust gas
86: fourth exhaust gas 87: third suction fluid
88: fourth suction fluid 90: power transmission portion
91: first power transmitting portion 92: second power transmitting portion
100: Storage tank 200: First supply line
300: compressor 400: second supply line
500: customer demand 700: turbocharger
710: Turbine 720: Compressor
810: first exhaust gas 820: second exhaust gas
830: first suction fluid 840: second suction fluid

Claims (5)

A supply line connecting the storage tank and the customer;
A compressor provided in the supply line to pressurize the evaporation gas in the storage tank and send it to a customer; And
And a turbocharger for pressurizing the intake fluid supplied to the engine by using exhaust gas discharged from the engine,
Wherein the turbocharger presses the suction fluid and uses the remaining energy as power for driving the compressor. The method according to claim 1,
Wherein the turbocharger includes a turbine through which the exhaust gas passes and a compressor through which the intake fluid passes,
Wherein the compressor is powered from the compressor through the power transmission. The method according to claim 1,
Wherein the turbocharger includes a first turbocharger and a second turbocharger, which are provided on both left and right sides of the engine,
Wherein the compressor is connected using the first turbocharger and the first power transmission unit and the second turbocharger is connected using the second power transmission unit. A supply line connecting the storage tank and the customer;
A compressor provided in the supply line to pressurize the evaporation gas in the storage tank and send it to a customer; And
And a turbocharger for pressurizing the suction fluid supplied to the customer using the exhaust gas discharged from the customer,
Wherein the turbocharger presses the suction fluid and uses the remaining energy as power for driving the compressor. 5. The method of claim 4,
Wherein the turbocharger includes a turbine through which the exhaust gas passes and a compressor through which the intake fluid passes,
Wherein the compressor is directly connected to the compressor.

Images