KR101665504B1 - Apparatus for supplying fuel gas of ship and method for changing mode of the same - Google Patents

Abstract

The present invention relates to a method of converting a mode of a fuel gas supply device of a ship into an operating mode of parallel operation in an HIVAR mode or a HI-COM mode. According to an aspect of the present invention, there is provided a fuel gas supply apparatus for a ship, comprising: a hicom which compresses a BOG of an LNG storage tank and converts the BOG into a temperature and a pressure required by the MEGI engine and supplies the same to the MEGI engine; The LNG storage tank is changed to a temperature and a pressure required by the MEGI engine and supplied to the MEGI engine; A first pressure sensor for measuring the pressure of the fuel gas discharged from the hi-comb and transmitting the measured first pressure to the sequence controller; A second pressure sensor for measuring a pressure of the fuel gas discharged from the high bar and transmitting the measured second pressure to the sequence controller; A third pressure sensor for measuring the pressure of the fuel gas supplied to the MEGI engine and transmitting the measured third pressure to the sequence controller; A first valve installed in a fuel gas supply line for supplying a fuel gas from the HiCom to the MEGI engine and controlling a fuel gas supply from the HiComm to the MEGI engine; A second valve installed in the fuel gas supply line for supplying the fuel gas from the high bar to the MEGI engine and controlling the fuel gas supply from the high bar to the MEGI engine; And a mode change command to the parallel operation mode in which the hi-comb and the hi-bar simultaneously supply the fuel gas to the MEGI engine, whether the fuel gas supply device of the ship is operating in the high- And if the second pressure is greater than the third pressure, the second valve is opened. If the first pressure is greater than the third pressure when the second valve is in the high-bar mode, There is provided a fuel gas supply apparatus for a ship including a sequence control section for opening a first valve.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a fuel gas supply system for a ship, and a mode switching method for the apparatus. [0002]

The present invention relates to a fuel gas supply device for a ship and a mode switching method of the device, and more particularly, to a fuel gas supply device for a ship which operates in an HIVAR mode or a HI-COM mode To the parallel operation mode.

In recent years, when heavy oil or MDO (Marine Diesel Oil), which is used as fuel for various engines in a ship, is burned, the seriousness of environmental pollution caused by various harmful substances contained in exhaust gas arises, The regulations on various engines of ships used as a ship have been strengthened, and the cost for satisfying such regulations is gradually increasing.

Accordingly, a ship using clean fuel such as LNG, LPG, CNG, or DME, which is gaseous fuel, is suggested as a solution instead of using oil such as heavy oil or MDO as fuel oil or using only a minimum amount of oil Many technologies are being developed.

As such technology, there is a MEGI engine for offshore structures such as ships, such as LNG carriers.

The MEGI engine consists of two strokes and adopts a diesel cycle in which high pressure natural gas near 300 bar is injected directly to the combustion chamber near the piston top dead center. The MEGI engine uses natural gas as the fuel of the engine, and depending on the load, a high-pressure fuel gas supply pressure of about 200 to 400 bara (absolute pressure) is required for the engine, and the temperature of the fuel gas is 40 to 50 ° C Is required. The MEGI engine is seen as an environmentally friendly next-generation engine that can reduce pollutant emissions by 23% for carbon dioxide, 80% for nitrogen compounds, and 95% for sulfur compounds compared to diesel engines in its class.

A method for supplying fuel to the MEGI engine is to convert the boil-off gas (BOG) into a fuel gas at a temperature and a pressure required by the engine and supply the LNG to the engine. And supplying it to the engine.

(HI-COM), which uses a high-pressure compressor to convert the BOG into a state of temperature and pressure required by the engine and supply it to the engine. The LNG is pressurized and heated using a high-pressure pump and a high- The device that supplies the engine with the required temperature and pressure is called HIVAR.

Generally, in the laden voyage, there is enough BOG in the LNG storage tank, so HiComm is used to supply fuel to MEGI and DFGE. In case of ballast voyage, HiVAR is used because BOG is not enough. To fuel MEGI and DFGE.

However, in the case of a lot of BOGs even during the ballast voyage, it is necessary to use HiComm. If you do not use a hiccom, you must burn the BOG using the Gas Combustion Unit (GCU). Therefore, during the ballast voyage, it may be more efficient to use the parallel operation mode in which the HiComm and HiBar simultaneously supply fuel gas to the engine. Further, even in the case of other than the ballast voyage, the flexibility of the fuel gas supply device of the ship can be improved by using the parallel operation mode.

Therefore, it is necessary to define a switching process for switching to a parallel operation mode while operating in a high-com mode or a high-bar mode.

Prior Art: Korea Publication No. 10-2008-0103500 (Published Nov. 27, 2008)

The present invention provides a mode switching method of a fuel gas supply apparatus for a ship that defines a process of switching to a parallel operation mode stably while operating in a highcomm mode or a highbar mode.

In accordance with an aspect of the present invention, there is provided a fuel gas supply apparatus for a ship, comprising: a fuel tank for supplying fuel to the MEGI engine by compressing the BOG of the LNG storage tank to a temperature and a pressure required by the MEGI engine, ; The LNG storage tank is changed to a temperature and a pressure required by the MEGI engine and supplied to the MEGI engine; A first pressure sensor for measuring the pressure of the fuel gas discharged from the hi-comb and transmitting the measured first pressure to the sequence controller; A second pressure sensor for measuring a pressure of the fuel gas discharged from the high bar and transmitting the measured second pressure to the sequence controller; A third pressure sensor for measuring the pressure of the fuel gas supplied to the MEGI engine and transmitting the measured third pressure to the sequence controller; A first valve installed in a fuel gas supply line for supplying a fuel gas from the HiCom to the MEGI engine and controlling a fuel gas supply from the HiComm to the MEGI engine; A second valve installed in the fuel gas supply line for supplying the fuel gas from the high bar to the MEGI engine and controlling the fuel gas supply from the high bar to the MEGI engine; And a mode change command to the parallel operation mode in which the hi-comb and the hi-bar simultaneously supply the fuel gas to the MEGI engine, whether the fuel gas supply device of the ship is operating in the high- And if the second pressure is greater than the third pressure, the second valve is opened. If the first pressure is greater than the third pressure when the second valve is in the high-bar mode, There is provided a fuel gas supply apparatus for a ship including a sequence control section for opening a first valve.

In particular, the sequence controller may determine whether a ratio of the gas supply amount of the HiComm and the gas supply amount of the HiBar satisfies a predetermined criterion.

Further, the fuel gas supply device of the ship may further include a first flow sensor for measuring the flow of the fuel gas discharged from the hicom and for transferring the measured first flow to the sequence controller; And a second flow sensor for measuring a flow of the fuel gas discharged from the high bar and transmitting the measured second flow to the sequence controller, wherein the sequence controller is configured to determine whether the difference between the first flow and the second flow If it is less than the predetermined error value, it can be determined that the ratio of the gas supply amount of the Hicomb and the gas supply amount of the high gas satisfies a certain criterion.

Further, the HiCom further includes a fifth valve, which is a bypass valve, for controlling the flow rate of the HiCom, and the sequence controller controls the flow rate of the HiCom gas supply amount and the flow rate of the HiCom when the opening degree of the fifth valve falls within a predetermined range. It can be determined that the ratio of the gas supply amount of the high bar satisfies a certain criterion.

The predetermined range may be 48% or more and 52% or less.

In addition, if the ratio of the gas supply amount of the Hicomb and the gas supply amount of the HiBar satisfies a certain criterion, the sequence controller can adjust the load of the HiCom.

In addition, the sequence controller may adjust the load of the HiComm in consideration of the pressure of the LNG storage tank and the pressure of the fuel gas supplied to the MEGI engine.

According to another aspect of the present invention, there is provided a method for switching a mode of a fuel gas supply apparatus for a ship, the method comprising: receiving a mode switching command to a parallel operation mode in which a HiComm and a HiBar simultaneously supply fuel gas to a MEGI engine; Receiving an input; Determining whether the fuel gas supply device of the ship is operating in a high-comb mode or a high-bar mode; And a fuel gas supply line for supplying the fuel gas from the high bar to the MEGI engine when the pressure of the fuel gas discharged from the high bar is higher than the pressure of the fuel gas supplied to the MEGI engine Opening a second valve; Determining whether a ratio of the gas supply amount of the hiccom and the gas supply amount of the high gas satisfy a predetermined criterion; Wherein the sequence control unit controls the load of the hiccom when the ratio of the gas supply amount of the hicom and the gas supply amount of the hiba satisfy a certain criterion.

In particular, the step of determining whether the ratio of the gas supply amount of the hicom and the gas supply amount of the hiba satisfy a certain standard may include determining a difference between the flow of the fuel gas discharged from the hicom and the flow of the fuel gas discharged from the hiba It is determined that the ratio of the gas supply amount of the Hicomb and the gas supply amount of the HiBar satisfies a predetermined criterion if the error is less than a predetermined value.

Further, the HiComm further includes a fifth valve, which is a bypass valve for controlling the flow rate of the HiCom, and determines whether the ratio of the gas supply amount of the HiCom to the gas supply amount of the HiCom satisfies a predetermined criterion May determine that the ratio of the gas supply amount of the HiComm and the gas supply amount of the HiBar satisfies a predetermined criterion when the opening degree of the fifth valve falls within a predetermined range.

The predetermined range may be 48% or more and 52% or less.

According to the embodiment of the present invention, it is possible to stably switch to the parallel operation mode while operating in the highcomm mode or the high-bar mode.

1 is a view showing a line in which a fuel gas supply device of a ship according to an embodiment of the present invention supplies fuel gas to a MEGI engine.
FIGS. 2 and 3 are flowcharts illustrating a process in which the fuel gas supply device of the ship is switched from a hiccom mode or a high-bar mode to a parallel operation mode according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In general, among the waste gases emitted from vessels, those regulated by the International Maritime Organization are nitrogen oxides (NOx) and sulfur oxides (SOx), and in recent years they have also been trying to regulate the emission of carbon dioxide (CO ₂ ) have. Particularly, in the case of nitrogen oxide (NOx) and sulfur oxides (SOx), it was raised through the Protocol of the Maritime Pollution Prevention Convention (MARPOL) in 1997, In May, the requirements for the fermentation were satisfied and the regulations are being implemented.

Accordingly, various methods for reducing nitrogen oxide (NOx) emissions have been introduced in order to meet these requirements. Of these methods, MEGI engines for marine structures such as ships such as LNG carriers have been developed and used.

The MEGI engine can also be used directly for propelling, for which the MEGI engine consists of a two-stroke engine rotating at low speed. That is, the MEGI engine is a low-speed two-stroke high-pressure natural gas injection engine.

The MEGI engine uses natural gas as the fuel of the engine, and depending on the load, a high-pressure fuel gas supply pressure of about 200 to 400 bara (absolute pressure) is required for the engine, and the temperature of the fuel gas is 40 to 50 ° C Is required.

The MEGI engine can be used as a propulsion engine.

The fuel gas supply apparatus for a ship according to the embodiment of the present invention includes Haicom and Haiba, and Haicom and Haiba supply fuel gas to the MEGI engine, respectively. Hence, a line is provided for supplying fuel gas to the MEGI engine, and a line for supplying fuel gas to the Hibaaga MEGI engine.

1 is a view showing a line in which a fuel gas supply device of a ship according to an embodiment of the present invention supplies fuel gas to a MEGI engine.

1, a fuel gas supplying apparatus for a ship according to an embodiment of the present invention includes an LNG storage tank 170, a high pressure compressor 150, a stripping pump 161, a high pressure pump 162, The sequence controller 140, the first pressure sensor 111, the second pressure sensor 112, the third pressure sensor 113, the fourth pressure sensor 114, the temperature sensor 121, A first flow sensor 181, a second flow sensor 182, a first valve 131 and a second valve 132.

The LNG storage tank 170 is a tank for storing the LNG. Since the liquefaction temperature of natural gas is a cryogenic temperature of about -163 ° C at normal pressure, natural gas evaporates even when the temperature is slightly higher than -163 ° C at normal pressure. The LNG is continuously vaporized in the LNG storage tank 170 so that the LNG is continuously evaporated in the LNG storage tank 170 and the evaporated gas (BOG, Boil) is stored in the LNG storage tank 170. Therefore, even if the LNG storage tank 170 is thermally insulated, -Off Gas) is generated, and the pressure inside the LNG storage tank 170 can be increased. Thus, the LNG storage tank 170 may be in the form of a pressure tank. Even if the LNG storage tank 170 is in the form of a pressure tank, the BOG should be discharged to the outside of the LNG storage tank 170 in order to prevent the pressure inside the LNG storage tank 170 from being continuously increased.

The MEGI engine can be selectively supplied with fuel gas or diesel. That is, it can operate in gas mode or diesel mode.

When the MEGI engine is operated in the gas mode, the BOG is supplied to the MEGI engine by making the temperature and the pressure required by the MEGI engine, or by pressurizing and heating the LNG to the temperature and pressure required by the MEGI engine, .

The system that supplies BOG to the engine with the temperature and pressure required by the engine is called HI-COM, and the LNG is pressurized and heated to produce the required temperature and pressure of the engine and supplied to the engine. The device is called HIVAR. The HiComm includes a high pressure compressor 150 and the HiBAR can include a stripping pump 161, a high pressure pump 162 and a high pressure evaporator 163. [

That is, the fuel gas supply device for a ship according to an embodiment of the present invention includes a hi-comb and a hi-bar, and a mode in which hi -comm supplies fuel gas to the engine is called a hi -comm mode, Mode is referred to as a high-bar mode, and a mode in which a high-com and a high-bar simultaneously supply fuel gas to the MEGI engine is referred to as a parallel operation mode.

The high pressure compressor 150 is connected to the LNG storage tank 170 through a fuel transfer line so that the BOG of the LNG storage tank 170 is transferred to the high pressure compressor 150 through the fuel transfer line. Then, the high-pressure compressor 150 compresses the BOG and compresses the BOG, so that the temperature of the BOG is increased, and the temperature and pressure of the BOG are changed to the temperature and pressure required by the MEGI engine and supplied to the MEGI engine.

As shown in FIG. 1, the high pressure compressor 150 may be a five-stage compressor.

The stripping pump 161 pressurizes the LNG stored in the LNG storage tank 170 to a few to several tens of bar and transfers it to the fuel transfer line.

The high pressure pump 162 pressurizes the LNG to a pressure required by the MEGI engine, for example, 200 to 400 bar, and the high pressure evaporator 163 pressurizes the LNG pressurized by the high pressure pump 162 to a temperature required by the MEGI engine . The fuel gas discharged from the high-pressure evaporator 163 is supplied to the MEGI engine.

The first pressure sensor 111 measures the pressure of the fuel gas discharged from the high pressure compressor 150 and transmits the measured first pressure to the sequence controller 140.

The second pressure sensor 112 measures the pressure of the fuel gas discharged from the high pressure evaporator 163 and transmits the measured second pressure to the sequence controller 140.

The third pressure sensor 113 measures the pressure of the fuel gas supplied to the first MEGI engine and transmits the measured third pressure to the sequence controller 140.

The fourth pressure sensor 114 measures the pressure of the fuel gas supplied to the second MEGI engine and transmits the measured fourth pressure to the sequence controller 140.

The temperature sensor 121 measures the temperature of the fuel gas supplied to the MEGI engine.

The first flow sensor 181 measures the flow of the fuel gas discharged from the high-pressure compressor 150 and transmits the measured flow to the sequence controller 140.

The second flow sensor 182 measures the flow of the fuel gas discharged from the high pressure evaporator 163 and transmits the measured second flow to the sequence controller 140.

The first valve 131 is installed in a fuel gas supply line for supplying fuel gas from the high-pressure compressor 150 to the MEGI engine, and controls the fuel gas supply from the high-pressure compressor 150 to the MEGI engine.

The second valve 132 is installed in the fuel gas supply line for supplying the fuel gas from the high-pressure evaporator 163 to the MEGI engine, and controls the fuel gas supply from the high-pressure evaporator 163 to the MEGI engine.

The first valve (131) and the second valve (132) are throttling valves and can control the pressure reduction and the flow rate.

The third valve 133 opens and closes the fuel gas supply line to the first MEGI engine and the fourth valve 134 opens and closes the fuel gas supply line to the second MEGI engine.

The fifth valve 135 controls the flow rate of the HiComm as a bypass valve. The sixth valve 136 controls the flow rate of the high-rate gas in consideration of the minimum flow rate of the high-pressure pump 162. That is, the high-pressure pump 162 must always discharge a predetermined minimum flow rate. If the required flow rate in the engine is lower than the minimum flow rate of the high-pressure pump 162, the sixth valve 136 is opened and discharged from the high-pressure pump 162 Some of the LNG is returned to the LNG storage tank 170, thereby controlling the discharge flow rate of the HVA.

When the sequence control unit 140 receives the mode switching command to the parallel operation mode while operating in the high-bar mode or the high-com mode, the sequence control unit 140 performs mode switching to the parallel operation mode.

The process by which the sequence controller 140 switches the mode of the fuel gas supply device to the parallel operation mode will be described with reference to FIG. FIGS. 2 and 3 are flowcharts illustrating a process in which the fuel gas supply device of the ship is switched from a hiccom mode or a high-bar mode to a parallel operation mode according to an embodiment of the present invention.

When the operator inputs a mode change command from the operator to the parallel operation mode (S201), the sequence controller 140 determines whether the fuel gas supply device of the ship is operating in the highcomm mode or the highbar mode (S202). If the vehicle is operating in the high-com mode, the process proceeds to step S203; otherwise, the process proceeds to step S221.

In step S203, the output pressure set values of the high-bar and high-comb are changed (S203). At this time, the output pressure setting value of the high bar may be changed to the required pressure of the MEGI engine, for example, 300 bar, and the output pressure setting value of the HiComm may be changed to a value smaller than the required pressure of the MEGI engine. To reduce the amount of fuel gas supplied by the hi-com to the engine and to supply the fuel gas to the hi-burn engine, the output pressure setting of the hi-bass is adjusted to the required pressure of the engine, To a value smaller than the required pressure.

Then, the sequence controller 140 determines whether the second pressure is greater than the third pressure and the fourth pressure (S204). If the second pressure is not greater than the third pressure and the fourth pressure, the sequence control unit 140 stops the mode switching to the MEGI engine (S211), and changes the output pressure set values of the HiCom and HiBar Modify it.

If the second pressure is greater than the third pressure and the fourth pressure, the sequence controller 140 opens the second valve 132 (S205). At this time, the sequence controller 140 can completely open the second valve 132. [

Then, the sequence control unit 140 changes the high-bar sensor from the second pressure sensor 112 to the third pressure sensor 113 and the fourth pressure sensor 114 (S206). The high-bar sensor refers to a sensor which is a standard for controlling the discharge pressure of the high-bar. That is, when the second valve 132 is closed, the discharge pressure of the high valve is adjusted based on the pressure value measured by the second pressure sensor 112. However, after the second valve 132 is opened, The fuel gas is supplied to the engine to change the high-bar sensor to adjust the discharge pressure of the high-pressure gas based on the pressure values of the third pressure sensor 113 and the fourth pressure sensor 114. [

Then, the sequence control unit 140 determines whether the fuel gas supply state to the MEGI engine is normal (S207). At this time, the sequence control unit 140 uses the pressure measured by the third pressure sensor 113, the pressure measured by the fourth pressure sensor 114, and the temperature measured by the temperature sensor 121, It is possible to determine whether the supply state is normal or not.

The sequence controller 140 determines that the pressure measured by the third pressure sensor 113 and the pressure measured by the fourth pressure sensor 114 are within a predetermined range from the pressure of the fuel gas required by the MEGI engine, Is within a certain range from the temperature of the fuel gas required by the MEGI engine, it can be determined that the fuel gas supply state to the MEGI engine is normal. For example, if the pressure required by the MEGI engine is 300 bar and the temperature required by the MEGI engine is 45 ° C, the pressure measured by the third pressure sensor 113 and the pressure measured by the fourth pressure sensor 114 are 290 bar or more and 310 bar or less and the temperature measured by the temperature sensor 121 is 35 DEG C or more and 55 DEG C or less, it is determined that the fuel gas supply state to the MEGI engine is normal.

If the fuel gas supply state to the MEGI engine is not normal, the sequence controller 140 stops the mode switching to the MEGI engine (S211). If the fuel gas supply state to the MEGI engine is normal, It is determined whether the ratio of the gas supply amount of the high bar meets a predetermined standard (S208).

In the embodiment of the present invention, there are proposed two methods of determining whether the ratio of the gas supply amount of HiComm and the gas supply amount of HiBAR satisfy a predetermined constant standard.

According to the first method, when the difference between the first flow measured by the first flow sensor 181 and the second flow measured by the second flow sensor 182 is equal to or less than a predetermined error value, It is determined that the ratio of the gas supply amount satisfies a predetermined constant criterion.

According to the second method, when the opening degree of the fifth valve 135 falls within a predetermined range, it is determined that the ratio between the gas supply amount of HiComm and the gas supply amount of HiBAR satisfies predetermined predetermined criteria. At this time, the predetermined range may be 48% or more and 52% or less.

If the ratio between the gas supply amount of the HiComm and the gas supply amount of the HiBAR does not satisfy the predetermined criterion, steps S207 and S208 are repeated until the preset timer expires (S212). If the timer expires, The switching is stopped (S211).

If the ratio of the gas supply amount of the Hicomb and the gas supply amount of the HiBar satisfies a certain criterion, the sequence control unit 140 adjusts the load of the HiCom (S209). At this time, the sequence controller 140 may adjust the load of the hiccom using the fifth valve in consideration of the pressure of the LNG storage tank 170 and the pressure of the fuel gas supplied to the MEGI engine. And, the high-bar load can be adjusted considering the pressure of the fuel gas supplied to the MEGI engine.

Then, the sequence control unit 140 displays a mode change completion message to the operator (S210).

Referring to FIG. 3, in step S221, the output pressure setting values of the high and low combs are changed (S221). At this time, the output pressure setting value of the HiComm may be changed to the required pressure of the MEGI engine, for example, 300, and the output pressure setting value of the HiBAR may be changed to a value smaller than the required pressure of the MEGI engine. In order to reduce the amount of fuel gas supplied to the engine, and to allow the engine to supply fuel gas to the engine, the HiComm output pressure setting is adjusted to the required pressure of the MEGI engine, To a value smaller than the required pressure.

Then, the sequence controller 140 determines whether the first pressure is greater than the third pressure and the fourth pressure (S222). If the first pressure is not greater than the third pressure and the fourth pressure, the sequence controller 140 stops the mode switching (S229) and modifies the HiCom and HiBar output pressure set values changed before the change in step S221.

 If the first pressure is greater than the third pressure and the fourth pressure, the sequence controller 140 opens the first valve 131 (S223). At this time, the sequence controller 140 can fully open the first valve 131. [

Then, the sequence control unit 140 changes the Hi-Com sensor from the first pressure sensor 111 to the third pressure sensor 113 and the fourth pressure sensor 114 (S224). Hi-Com sensors are sensors that are used to control HYCOM's exhaust pressure. That is, when the first valve 131 is closed, the discharge pressure of the high valve is adjusted based on the pressure value measured by the first pressure sensor 111. However, after the first valve 131 is opened, Since the fuel gas is supplied to the engine, the hycomcom sensor is changed to adjust the discharge pressure of the hicom based on the pressure values of the third pressure sensor 113 and the fourth pressure sensor 114. [

Then, the sequence control unit 140 determines whether the fuel gas supply state to the MEGI engine is normal (S225). At this time, the sequence control unit 140 uses the pressure measured by the third pressure sensor 113, the pressure measured by the fourth pressure sensor 114, and the temperature measured by the temperature sensor 121, It is possible to determine whether the supply state is normal or not.

The sequence controller 140 determines that the pressure measured by the third pressure sensor 113 and the pressure measured by the fourth pressure sensor 114 are within a predetermined range from the pressure of the fuel gas required by the MEGI engine, Is within a certain range from the temperature of the fuel gas required by the MEGI engine, it can be determined that the fuel gas supply state to the MEGI engine is normal. For example, if the pressure required by the MEGI engine is 300 bar and the temperature required by the MEGI engine is 45 ° C, the pressure measured by the third pressure sensor 113 and the pressure measured by the fourth pressure sensor 114 are 290 bar or more and 310 bar or less and the temperature measured by the temperature sensor 121 is 35 DEG C or more and 55 DEG C or less, it is determined that the fuel gas supply state to the MEGI engine is normal.

If the fuel gas supply state to the MEGI engine is not normal, the sequence controller 140 stops the mode switching (S229). If the fuel gas supply state to the MEGI engine is normal, the gas supply amount of the HiComm and the gas supply amount (S226). If the ratio satisfies the predetermined criterion (S226).

In the embodiment of the present invention, there are proposed two methods of determining whether the ratio of the gas supply amount of HiComm and the gas supply amount of HiBAR satisfy a predetermined constant standard.

According to the first method, it is determined whether the difference between the first flow measured by the first flow sensor 181 and the second flow measured by the second flow sensor 182 is equal to or less than a predetermined error value.

According to the second method, it is determined whether or not the opening degree of the fifth valve 135 falls within a predetermined range. At this time, the predetermined range may be 48% or more and 52% or less.

If the ratio between the gas supply amount of the hiccom and the gas supply amount of the high gas does not satisfy the predetermined constant standard, steps S225 and S226 are repeated until the predetermined timer expires (S230), and when the timer expires, (S229).

If the ratio of the gas supply amount of the HiComm and the gas supply amount of the HiBAR satisfies a certain criterion, the sequence control unit 140 adjusts the load of the HiComm (S227). At this time, the sequence controller 140 may adjust the load of the hiccom using the fifth valve in consideration of the pressure of the LNG storage tank 170 and the pressure of the fuel gas supplied to the MEGI engine. And, the high-bar load can be adjusted considering the pressure of the fuel gas supplied to the MEGI engine.

Then, the sequence control unit 140 displays a mode change completion message to the operator (S228).

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

170: LNG storage tank
150: High pressure compressor
161: stripping pump
162: High pressure pump
163: High-pressure evaporator
140: Sequence control unit
111: first pressure sensor
112: second pressure sensor
113: third pressure sensor
114: fourth pressure sensor
121: Temperature sensor
181: first flow sensor
182: second flow sensor
131: first valve
132: second valve

Claims (11)

In a fuel gas supply system for a ship,
Hycom, which compresses the BOG of the LNG storage tank and changes it to the temperature and pressure required by the MEGI engine and supplies it to the MEGI engine;
The LNG storage tank is changed to a temperature and a pressure required by the MEGI engine and supplied to the MEGI engine;
A first pressure sensor for measuring the pressure of the fuel gas discharged from the hi-comb and transmitting the measured first pressure to the sequence controller;
A second pressure sensor for measuring a pressure of the fuel gas discharged from the high bar and transmitting the measured second pressure to the sequence controller;
A third pressure sensor for measuring the pressure of the fuel gas supplied to the MEGI engine and transmitting the measured third pressure to the sequence controller;
A first valve installed in a fuel gas supply line for supplying a fuel gas from the HiCom to the MEGI engine and controlling a fuel gas supply from the HiComm to the MEGI engine;
A second valve installed in the fuel gas supply line for supplying the fuel gas from the high bar to the MEGI engine and controlling the fuel gas supply from the high bar to the MEGI engine; And
When the hi-comb and the hi-bar simultaneously receive a mode switching command to the parallel operation mode for supplying the fuel gas to the MEGI engine, it is determined whether the fuel gas supply device of the ship is operating in the high- If the second pressure is greater than the third pressure, the second valve is opened. If the first pressure is higher than the third pressure when the second valve is in the high-mode mode, And a sequence controller for opening one valve,
Wherein the sequence control unit comprises:
Controls the opening and closing of the first or second valve for controlling the fuel gas supply from the hiccom or the high-bar by comparing the pressure of the fuel gas discharged from the hi-comb or the high-bar with the pressure of the fuel gas supplied to the MEGI engine ,
When the first and second valves are both open and the ratio of the gas supply amount of the fuel gas supply line from the HiComm and HiBar is measured and the reference range value is satisfied, the load of the HiCom is adjusted to control the pressure of the LNG storage tank Wherein the fuel gas is supplied to the fuel tank. delete The method according to claim 1,
The fuel gas supply device of the ship
A first flow sensor for measuring the flow of the fuel gas discharged from the hiccom and transmitting the measured first flow to the sequence controller; And
Further comprising a second flow sensor for measuring a flow of the fuel gas discharged from the high bar and transmitting the measured second flow to the sequence controller,
Wherein the sequence controller determines that the ratio of the gas supply amount of the HiComm and the gas supply amount of the high bar satisfies a predetermined criterion when the difference between the first flow and the second flow is less than a predetermined error value, . The method according to claim 1,
The HiComm further includes a fifth valve which is a bypass valve for controlling the flow rate of the HiCom,
Wherein the sequence controller determines that the ratio of the gas supply amount of the HiComm and the gas supply amount of the HiBar satisfies a predetermined criterion when the opening degree of the fifth valve falls within a predetermined range. The method of claim 4,
Wherein the predetermined range is 48% or more and 52% or less. The method according to claim 1,
Wherein the sequence controller adjusts the load of the hiccom when the ratio of the gas supply amount of the hiccom and the gas supply amount of the hiba satisfy a certain criterion. The method of claim 6,
Wherein the sequence controller adjusts the load of the hicom in consideration of the pressure of the LNG storage tank and the pressure of the fuel gas supplied to the MEGI engine. A method of switching a mode of a fuel gas supply system of a ship,
Receiving a mode switching command to a parallel operation mode in which a hybrid vehicle and a hybrid vehicle simultaneously supply fuel gas to a MEGI engine;
Determining whether the fuel gas supply device of the ship is operating in a high-comb mode or a high-bar mode;
And a fuel gas supply line for supplying the fuel gas from the high bar to the MEGI engine when the pressure of the fuel gas discharged from the high bar is higher than the pressure of the fuel gas supplied to the MEGI engine Opening a second valve;
Determining whether a ratio of the gas supply amount of the hiccom and the gas supply amount of the high gas satisfy a predetermined criterion;
And controlling a load of the hiccom when the ratio of the gas supply amount of the hicom and the gas supply amount of the hiba satisfy a predetermined criterion,
Wherein the sequence control unit comprises:
Controls the opening and closing of the first or second valve for controlling the fuel gas supply from the hiccom or the high-bar by comparing the pressure of the fuel gas discharged from the hi-comb or the high-bar with the pressure of the fuel gas supplied to the MEGI engine ,
When the first and second valves are all opened and the ratio of the gas supply amount of the fuel gas supply line from the HiComm and HiBar is measured and the reference range value is satisfied,
And adjusting the pressure of the LNG storage tank by adjusting the load of the hiccom. The method of claim 8,
Wherein the step of determining whether the ratio of the gas supply amount of the hiccom and the gas supply amount of the high gas satisfy a predetermined criterion
When the difference between the flow of the fuel gas discharged from the hi-comb and the flow of the fuel gas discharged from the hi-bar is less than a predetermined error value, it is judged that the ratio of the gas supply amount of the hi-comb to the gas supply amount of the hi-bar satisfies a certain criterion , Mode switching method. The method of claim 8,
The HiComm further includes a fifth valve which is a bypass valve for controlling the flow rate of the HiCom,
Wherein the step of determining whether the ratio of the gas supply amount of the hiccom and the gas supply amount of the high gas satisfy a predetermined criterion
And when the opening degree of the fifth valve falls within a predetermined range, it determines that the ratio of the gas supply amount of the Hicomb and the gas supply amount of the high valve satisfies a certain criterion. The method of claim 10,
Wherein the predetermined range is 48% or more and 52% or less.

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