JP6668566B2 - Fuel gas supply system, ship, and fuel gas supply method - Google Patents

Description

  The present invention relates to a fuel gas supply system that supplies a boil-off gas vaporized from a liquefied gas as a fuel gas to an engine, a ship using the system, and a fuel gas supply method.

  In an LNG (liquefied natural gas) carrier, boil-off gas is vaporized from liquefied gas stored in a tank. In order to effectively process the boil-off gas, the boil-off gas is supplied to a ship engine as a fuel gas.

A low pressure fluid, such as boil-off gas, needs to be a high pressure fluid in order to be adapted as engine fuel gas. Therefore, in a fuel gas supply system that supplies boil-off gas as fuel gas for an engine, a fuel such as boil-off gas is pressurized (compressed) using, for example, a multi-stage pressurizing device. The pressurized fuel is delivered to the engine.
On the other hand, the demand for fuel gas of the engine may change due to load fluctuation or the like. In this case, it is desired to control the amount of fuel delivered by the fuel gas supply system according to the load fluctuation of the engine.

For example, there is known a ship that can supply fuel gas of different pressures to two or more gas-fired diesel engines and can save space (Patent Document 1).
It is stated that in this ship, fluctuations in supply gas pressure can be suppressed to an allowable range by controlling the number of rotations of a high-pressure pump, which is a pressurizing device, the opening of a flow control flight, and a pressure regulating valve.

JP 2016-49881 A

However, in the above-mentioned ship, when the load of some of the plurality of operating engines suddenly changes, for example, another engine enters an operation ready state while some of the engines are operating, and this engine upstream. When the flow control valve is opened, a large amount of fuel gas flows into the engine, and as a result, the pressure of the fuel gas in the pipe rapidly decreases, and the fuel gas supplied to some of the above-mentioned engines during operation is reduced. Is much lower than the required pressure. In addition, when a part of the engines is stopped due to a trouble or the like during the operation of the plurality of engines, there is a possibility that the pressure of the fuel gas in the pipe rapidly increases due to a rapid decrease in the consumption of the fuel gas.
Such a problem may occur not only in a plurality of engines but also in a case where a load changes rapidly in one engine. As described above, it is difficult to change the supply amount of the fuel gas supplied from the fuel gas supply system in response to a sudden change in the load of the engine. Further, the above-mentioned ship does not disclose how to control the supply amount of the fuel gas.

  In view of the above, the present invention provides a fuel gas control system capable of controlling the supply of fuel gas so as to respond to the engine load fluctuation even when a sudden engine load fluctuation occurs, thereby supplying a stable fuel gas to the engine. It is an object to provide a supply system, a fuel gas supply method, and a ship.

One embodiment of the present invention is a fuel gas supply system that supplies a fuel gas to an engine. The fuel gas supply system includes:
A tank for storing liquefied gas,
A pressurizing mechanism that pressurizes and sends out the boil-off gas or the liquefied gas vaporized from the liquefied gas as fuel to supply the boil-off gas vaporized from the liquefied gas to the engine as a fuel gas,
A pressurization control device that controls the amount of fuel delivered by the pressurization mechanism,
A main pipe connecting the pressurizing mechanism and an engine, and through which the fuel delivered by the pressurizing mechanism flows to the engine.
The control of the delivery amount performed by the pressurization control device includes controlling the delivery amount based on a difference between a set pressure determined based on a required pressure of fuel required by the engine and a measured pressure of the fuel in the main pipe. Feedback control for controlling, and feedforward control for controlling the delivery amount based on the time change when the time change of the gas load signal indicating the fuel gas consumption of the engine exceeds a predetermined range and becomes large. Including.

One embodiment of the present invention is a fuel gas supply system that supplies a fuel gas to an engine. The fuel gas supply system includes:
A tank for storing liquefied gas,
A pressurizing mechanism that pressurizes and sends out the boil-off gas or the liquefied gas vaporized from the liquefied gas as fuel to supply the boil-off gas vaporized from the liquefied gas to the engine as a fuel gas,
A pressurization control device that controls a delivery amount of the fuel that the pressurization mechanism delivers,
A main pipe that connects the pressurizing mechanism and the engine, and in which the fuel delivered by the pressurizing mechanism flows to the engine.
The control of the delivery amount performed by the pressurization control device is performed based on a difference between a set pressure determined based on a required pressure of the fuel required by the engine and a measured pressure of the fuel in the main pipe. Feedback control that controls the amount of fuel gas consumed by the engine, and feed forward control that controls the delivery amount based on a change in a gas load signal indicating the consumption amount of the fuel gas,
The main Piping, closing valve is provided to supply the ON / OFF of the fuel gas to the engine,
The control of the delivery amount performed by the pressurization control device further includes a feedforward control of controlling the delivery amount based on information on a change of the on-off valve from on to off or from off to on.

  It is preferable that the pressurization control device controls the delivery amount such that the control amount of the delivery amount is adjusted according to the set pressure.

A pressurizing device configured to pressurize the fuel, a bypass pipe connecting a pipe through which fuel flows before and after pressurization by the pressurizing device, bypassing the pressurizing device; A regulating valve for controlling the amount of fuel flowing through the
It is preferable that the pressurization control device controls the delivery amount by controlling an opening degree of the adjustment valve using the feedforward control.

A pressurizing device configured to pressurize the fuel, a bypass pipe connecting a pipe through which fuel flows before and after pressurization by the pressurizing device, bypassing the pressurizing device; A plurality of sets comprising an adjustment valve for controlling the amount of fuel flowing through, a multi-stage pressurizing mechanism provided in series,
It is preferable that the pressurization control device controls the delivery amount by controlling an opening degree of each of the plurality of sets of adjustment valves using the feedforward control.

Another aspect of the present invention,
The fuel gas supply system;
A propulsion engine driven using fuel pressurized by the pressurizing mechanism,
And a control unit for controlling the propulsion engine.

Another embodiment of the present invention relates to a fuel gas supply method for supplying a fuel gas to an engine. The fuel gas supply method is as follows:
In order to supply the boil-off gas vaporized from the tank storing the liquefied gas as a fuel gas to a plurality of engines, pressurizing and sending the boil-off gas vaporized from the liquefied gas or the liquefied gas as fuel,
Feedback controlling the delivery amount based on a difference between a set pressure determined based on a required pressure of the fuel required by the engine and a measured pressure of the pressurized fuel,
Feed-forward controlling the delivery amount based on a change in a gas load signal indicating a fuel gas consumption amount of the engine.
The feedforward control is performed when the time change of the gas load signal becomes larger than a predetermined range.

Another embodiment of the present invention relates to a fuel gas supply method for supplying a fuel gas to an engine. The fuel gas supply method is as follows:
In order to supply the boil-off gas vaporized from the tank storing the liquefied gas as a fuel gas to a plurality of engines, pressurizing and sending the boil-off gas vaporized from the liquefied gas or the liquefied gas as fuel,
Feedback controlling the delivery amount of the fuel based on the difference between the set pressure determined based on the required pressure of the fuel required by the engine and the measured pressure of the fuel pressurized,
Feedforward controlling the delivery amount based on a change in a gas load signal indicating the fuel gas consumption amount of the engine.
The feedforward control is performed when the fluctuation of the gas load signal is out of a predetermined range,
Further comprising the based on a change from ON of the switching valve for supplying the on / off of the fuel gas from off to on or off, the step of the feed-forward control for controlling the delivery rate for each engine.

  In the control of the delivery amount, it is preferable that the control amount of the delivery amount is adjusted according to the set pressure.

Pressurization and delivery of fuel are performed by a pressurizing mechanism,
The pressurizing mechanism includes a pressurizing device that pressurizes the fuel, and a bypass pipe connected between a pipe through which fuel flows before and after pressurization by the pressurizing device, bypassing the pressurizing device,
It is preferable that the control of the delivery amount is performed by controlling the flow rate of the fuel flowing through the bypass pipe using the feedforward control.

Pressurization and delivery of fuel are performed by a pressurizing mechanism,
The pressurizing mechanism includes a pressurizing device that pressurizes the fuel, and a bypass pipe that connects a pipe through which the fuel flows before and after pressurization by the pressurizing device, bypassing the pressurizing device. Is a multi-stage pressurizing mechanism provided in series,
It is preferable that the control of the delivery amount is performed by controlling the flow rate of the fuel flowing through the bypass pipe in each of the plurality of sets using the feedforward control.

  According to the fuel gas supply system, the fuel gas supply method, and the marine vessel of the above aspect, even if a sudden change in the load of the engine occurs, the supply of the fuel gas is controlled so as to respond to the change in the load of the engine, and the fuel gas is stabilized. Fuel gas can be supplied to the engine.

It is a figure showing an example of composition of a fuel gas supply system of one embodiment. It is a figure showing an example of composition of a pressurizing mechanism of one embodiment. It is a figure showing the example of composition of the pressurizing mechanism of other one embodiment. It is a control block diagram of an example of control which a pressurization control device of one embodiment performs. It is a control block diagram of an example of control performed by the pressurization control device of another embodiment. FIG. 4 is a diagram illustrating an example of a relationship between a correction coefficient and a set pressure used in control of one embodiment.

Hereinafter, the fuel gas supply system and the fuel gas supply method of the present invention will be described in detail.
FIG. 1 is a diagram illustrating an example of a configuration of a fuel gas supply system 10 that supplies a boil-off gas of a liquefied gas as a fuel gas to a propulsion engine of a ship according to the present embodiment. Liquefied natural gas (LNG) is used as the liquefied gas of the fuel gas supply system 10, but is not limited to liquefied natural gas, and a liquefied gas such as pure methane gas or ethane gas can be used. The boil-off gas includes, in addition to the gas vaporized by natural heat input in the tank, a gas that is intentionally heated to forcibly vaporize LNG (liquefied natural gas). In the present embodiment, a description will be given using a gas vaporized by natural heat input in the tank. When a gas that has been forcibly vaporized is used, a forced vaporizer for forcibly vaporizing the liquefied gas is provided, and the liquefied gas is vaporized before being pressurized.
In this embodiment, the object to be pressurized is a boil-off gas, but may be a liquefied gas. In this case, as the pressurizing mechanism, a high-pressure pump for pressurizing the liquefied gas is used instead of the gas compressor of the present embodiment. In this case, it is preferable to use a heat exchanger that applies heat to the liquefied gas to bring it into a gas state after the liquefied gas is pressurized.

The fuel gas supply system 10 is used to supply the boil-off gas vaporized in the tank 20 storing the liquefied natural gas to the propulsion engines 40a and 40b as a fuel gas in an LNG carrier that transports the liquefied natural gas. The present embodiment includes a main pipe 31 through which boil-off gas (hereinafter, also referred to as fuel gas) delivered by the pressurizing mechanism 30 flows. In the present embodiment, one propulsion engine 40 is provided, but two, three, or four or more propulsion engines may be provided. In this case, the plurality of propulsion engines are connected to branch pipes branched from the main pipe 31 and provided for each propulsion engine.
In this specification, the direction in which boil-off gas is supplied from the tank 20 to the propulsion engine 40 is referred to as a downstream direction, the opposite direction is referred to as an upstream direction, and the downstream side from a reference position is referred to as a downstream side. Is referred to as the upstream side from the position.

The fuel gas supply system 10 of the present embodiment mainly includes a tank 20, a pressurizing mechanism 30, and a liquefaction device 50. A pressurizing mechanism 30 is provided on a main pipe 31 through which boil-off gas extends from the tank 20 to the propulsion engine 40.
The pressurizing mechanism 30 is a device that pressurizes and sends the boil-off gas vaporized from the liquefied gas to supply a part of the boil-off gas to the propulsion engine 40 as a fuel gas.
The liquefaction device 50 is a device for liquefying a part of the boil-off gas sent out by being pressurized by the pressurizing mechanism 30 and returning it to the tank 20.

(Pressure mechanism)
FIG. 2 is a diagram illustrating an example of the configuration of the pressing mechanism 30. The pressurizing mechanism 30 includes a gas compressor 32a to 32e, a bypass pipe 33a to 33e, an adjustment valve 34a to 34e, a suction snubber 35a to 35e, a discharge snubber 36a to 36e, and a heat exchanger 37a to 37e. Prepare mainly.
The suction snubbers 35a to 35e are containers provided with a space configured to temporarily store the boil-off gas upstream of the gas compressors 32a to 32e so that the boil-off gas is smoothly sucked by the gas compressors 32a to 32e. The discharge snubbers 36a to 36e are containers provided with a space downstream of the gas compressors 32a to 32e, in which the boil-off gas is temporarily stored so that the boil-off gas can be smoothly delivered. The heat exchangers 37a to 37e are provided on the downstream side of the discharge snubbers 36a to 36e, and cool the boil-off gas which has become hot when pressurized.

The gas compressors 32a to 32e are multi-stage pressurizing devices connected in series for compressing and sending out boil-off gas. The gas compressors 32a to 32e are portions that suck the boil-off gas in the suction snubbers 35a to 35e and pressurize the gas to a predetermined pressure. As the gas compressors 32a to 32e, for example, a reciprocating compressor is used in which a movable portion (plunger or piston) in the gas compressors 32a to 32e draws gas from the suction snubbers 35a to 35e by linearly reciprocating and then pressurizes. be able to. Among the gas compressors 32a to 32e, the gas compressors 32a to 32d use oilless compressors, and the gas compressor 32e that pressurizes the boil-off gas to a high pressure uses an oil supply compressor. The movable parts of the gas compressors 32a to 32e are driven in conjunction with each other via a rotating shaft that is rotated by the power of a driving source (not shown) whose driving is controlled by the pressurization control device 62. In the gas compressors 32a to 32e, the boil-off gas is compressed stepwise at approximately the same compression rate, so that the boil-off gas is compressed to the fifth power of the compression rate. For example, by compressing the three to four times in each of the gas compressors 32 a to 32 e, BOG is compressed in ³ 5-4 ⁵ times. For example, if the pressure of the boil-off gas on the suction side of the gas compressor 32a is 0.1 MPa, the pressure on the discharge (delivery) side of the gas compressor 32a is about 0.33 MPa, and the pressure on the discharge side of the gas compressor 32b is about 1. The pressure on the discharge side of the gas compressor 32c is about 3.64 MPa, and the pressure on the discharge side of the gas compressor 32d is about 12.06 MPa. Then, the pressure on the discharge side of the gas compressor 32e is increased to a set target pressure, for example, 39.9 Mpa.

The bypass pipe 33a connects the suction snubber 35a and the output end of the heat exchanger 37a, bypassing the gas compressor 32a, that is, the pipe section through which the boil-off gas flows before pressurization by the gas compressor 32a and the gas compressor 32a. A pipe through which boil-off gas flows, which connects pipes through which boil-off gas flows after pressurization. The bypass pipes 33b to 33d connect the corresponding suction snubbers 35b to 35d and the output ends of the corresponding heat exchangers 37b to 37d, bypassing the corresponding gas compressors 32b to 32d, that is, by the gas compressors 32b to 32d. The pipe through which the boil-off gas flows is connected between the pipe section through which the boil-off gas flows before the pressurization and the pipe through which the boil-off gas flows after the pressurization by the corresponding gas compressors 32b to 32d.
The bypass pipe 33e connects the suction snubber 35e and the output end of the heat exchanger 37e, bypassing the gas compressor 32e, that is, the pipe section through which the boil-off gas flows before pressurization by the gas compressor 32e and the gas compressor 32e. A pipe through which boil-off gas flows, which connects pipes through which boil-off gas flows after pressurization.
The bypass pipes 33a to 33d are provided with adjusting valves 34a to 34e that can adjust the opening degree of the valves. Further, pressure gauges 38a to 38d for measuring the pressure of the boil-off gas pressurized by the gas compressors 32a to 32d are provided in the bypass pipes 33a to 33d, respectively. The opening of each of the adjustment valves 34a to 34d is adjusted based on the pressure information measured by the pressure gauges 38a to 38d. A pressure gauge 38e that measures the pressure of the boil-off gas after being pressurized by the gas compressor 32e is provided downstream of the bypass pipe 33e in the main pipe 31. The opening of the adjustment valve 34e is adjusted based on the pressure information measured by the pressure gauge 38e. Specifically, information on the measured pressure measured by the pressure gauges 38a to 38e is supplied to a pressure control device 62c (see FIG. 1) described later, and the measured pressure is set by the pressure control device 62c. Is supplied to the adjustment valves 34a to 34e as a control signal for feedback control for controlling the amount of boil-off gas flowing through the bypass pipes 33a to 33e based on the difference between.

For example, when 1500 kg of boil-off gas is supplied per hour from the upstream side, and when the gas compressors 32a to 32e pressurize 2000 kg of boil-off gas per hour and send it to the downstream side, the corresponding bypass pipes 33a to 33e have 1 500 kg of boil-off gas is flowed per hour and returned to the upstream side of the gas compressors 32a to 32e. In this way, the opening degrees of the adjustment valves 34a to 34e provided in the bypass pipes 33a to 33e are controlled so that 500 kg of the boil-off gas flows per hour. Thereby, the pressure on the downstream side of the gas compressors 32a to 32e can be adjusted to a predetermined pressure. By adjusting the pressure to a predetermined value, the boil-off gas flowing from the pressurizing mechanism 30 toward the propulsion engine 40 can be set to the required pressure and fuel supply amount required by the propulsion engine 40.
In the present embodiment, the bypass pipes 33a to 33e are provided so as to bypass each of the gas compressors 32a to 32e. However, according to one embodiment, at least two of the adjacent gas compressors 32a to 32e are provided. As one set, a bypass pipe is preferably provided to bypass this set of compressors. FIG. 3 is a diagram illustrating an example of a configuration of an embodiment of the pressing mechanism 30. The example shown in FIG. 3 has a configuration in which a bypass pipe 33a is provided so as to bypass the gas compressors 32a and 32b simultaneously, and a bypass pipe 33c is provided so as to bypass the gas compressors 32c and 32d simultaneously.

In the pressurizing mechanism 30 of the embodiment shown in FIGS. 2 and 3, a check valve 38 is provided between the fourth stage gas compressor 32d and the fifth stage surface gas compressor 32e. The gas compressor 32d, which is an oil-free compressor, and the gas compressors 32a, 32b, 32c upstream thereof flow out of the oil-filled compressor contained in the boil-off gas delivered from the gas compressor 32e, which is an oil-filled compressor. A check valve 38 is provided to prevent impurities such as oil from flowing into the gas compressor 32d and contaminating devices such as the gas compressors 32a, 32b, and 32c upstream thereof.
According to one embodiment, it is also preferable to provide a check valve between the first stage gas compressor 32a and the second stage surface gas compressor 32b counted from the upstream side.
Further, according to one embodiment, it is also preferable to provide a check valve downstream of the bypass pipe 33e so that the boil-off gas once supplied to the propulsion engine 40 does not flow backward toward the upstream side.

The bleeding pipe branches from the junction between the bypass pipe 33b from the main pipe 31 and the junction of the bypass pipe 33c with the main pipe 31, and is connected to the gas treatment device 70 (see FIG. 2, FIG. 1). , The gas processing device 70 is not shown). The gas processing device 70 is a device that processes boil-off gas, and is exemplified by a boiler and a generator engine.
An adjustment valve is provided in a pipe extending to the gas processing device 70, and can be configured to adjust the amount of boil-off gas to be processed by the gas processing device 70.

(Propulsion engine)
The propulsion engine 40 is provided on the boat used in the present embodiment. The fuel gas supply system 10 of the present embodiment includes a piping mechanism including a main piping 31 through which the boil-off gas sent out by the pressurizing mechanism 30 flows. The propulsion engine 40 may be, for example, a dual fuel engine that uses boil-off gas of liquefied gas as fuel gas and can selectively use oil such as heavy oil as fuel.

  The propulsion engine 40 takes out power by burning the supplied boil-off gas as fuel gas in a combustion chamber, and rotates the main shaft 45 and the propeller 46 of the ship. As the propulsion engine 40, for example, a two-stroke cycle low-speed diesel engine can be used.

  The propulsion engine 40 is connected to an engine control unit (hereinafter, referred to as ECU) 60, and its driving is controlled by the ECU 60. The ECU 60 is provided on the main pipe 31 that supplies fuel gas to the propulsion engine 40 such that the main shaft rotation speed measured by the tachometer 42 provided to measure the rotation of the main shaft 45 becomes the target rotation speed. The driving of the propulsion engine 40 is controlled by controlling the opening of the pressure control valve 64. That is, the ECU 60 determines the load on the propulsion engine 40 so that the main shaft rotation speed of the main shaft 45 connecting the propulsion engine 40 and the propulsion propeller 46 becomes the target rotation speed, and controls the pressure of the fuel gas based on the load. It is a device to do. The ECU 60 determines the load on the propulsion engine 40 so that the main shaft rotation speed that changes due to changes in natural conditions such as weather, sea phenomena wind, and wave height is maintained at the target rotation speed. The load on the propulsion engine 40 can also be determined according to the operation command value of the propeller speed provided by the instruction. The ECU 60 is configured to set a target pressure on the delivery side of the gas compressor 32e located at the most downstream position based on the determined load, and to send the target pressure to a control integrated device 62c (see FIG. 1) described later. I have. This target pressure is the required pressure of the fuel gas required by the propulsion engine 40. Using the required pressure, the control integration device 62c controls the amount of boil-off gas delivered from the pressurizing device 30. Control of the amount of boil-off gas delivered will be described later.

(Liquefaction equipment)
The liquefaction apparatus 50 is connected to the pressurizing mechanism 30 through a bleed pipe 51 that branches off from a branch point of the bypass pipe 33c from the main pipe 31 and the check valve 38.
The liquefaction device 50 is a device that returns the boil-off gas that has become unnecessary due to a change in the load of the propulsion engine 40 to the tank 20 as liquefied gas. Part of the boil-off gas is not liquefied and maintains a gas. This boil-off gas merges with the boil-off gas which is sucked from the tank 20 by the pressurizing device 30 and flows as needed, and is pressurized by the pressurizing device 30 again. Although not shown, the liquefier 50 includes, for example, a heat exchanger that cools the boil-off gas before liquefying the boil-off gas, an expansion valve that expands and liquefies the cooled boil-off gas, and a gas-liquid mixed fluid created by the expansion valve. A gas-liquid separator, a gas pipe for joining the separated gas to a boil-off gas which is sucked from the tank 20 by the pressurizing device 30 and a liquefied gas pipe for flowing the separated liquefied gas to the tank.

(Control of the amount of boil-off gas delivered by the pressurizing mechanism)
To control the amount of boil-off gas delivered by the pressurizing mechanism 30 in the present embodiment, the pressurizing mechanism 30, the ECU 60, the pressure controller 61, the pressurizing control device 62, the pressure control valve 64, the pressure gauge 65 And an opening / closing valve 66 are mainly used. The control of the amount of boil-off gas delivered by the pressurizing mechanism 30 is performed by controlling the amount of boil-off gas flowing through the bypass pipe 33e in the pressurizing mechanism 30. The control of the amount of the boil-off gas flowing through the bypass pipe 33e is performed by controlling the opening of the regulating valve 34e. The control of the opening degree is performed using control signals FFw, FFv, and FBp generated by the pressurization control device 62, as described later.

  The pressure control valve 64 is provided in the main pipe 31, and controls the pressure of the boil-off gas flowing into the downstream portion of the main pipe 31 with respect to the pressurizing mechanism 30 by the opening of the pressure control valve 64. The opening of the pressure control valve 64 is controlled by a control signal sent from the pressure controller 61. The opening of the pressure control valve 64 is controlled such that the pressure measured by the pressure gauge 65 provided in the main pipe 31 becomes the required pressure determined by the ECU 60. In this way, by controlling the pressure of the boil-off gas to each required pressure, a predetermined supply amount of the boil-off glass is supplied to the propulsion engine 40 as fuel.

  Further, the main pipe 31 is provided with an opening / closing valve 66 for turning on / off the supply of fuel to the propulsion engine 40. ON / OFF of fuel supply by the opening / closing valve 66 is controlled by a control signal from the ECU 60. For example, when starting the propulsion engine 40, the open / close valve 66 is opened. When the fuel used by the propulsion engine 40 is changed from boil-off gas to oil such as heavy oil while the driving of the propulsion engine 40 is maintained, the on-off valve 66 may be closed while the rotation of the propulsion engine 40 is maintained. Assuming such a case, the opening and closing of the on-off valve 66 is controlled by a control signal from the ECU 60. The opening / closing valve 66 may be constituted by a gas valve train including a plurality of valves and a flow path.

The ECU 60 sends a control signal to the propulsion engine 40 such that the rotation speed of the propulsion engine 40 becomes a target rotation speed determined according to the set load. The ECU 60 sets the required pressure of the fuel gas required by the propulsion engine 40 according to the load of the propulsion engine 40, and transmits the information on the required pressure to the pressure controller 61 and the control integrated device 62c (see FIG. 1). send. Further, the ECU 60 sends a gas load signal ACL indicating information on the amount of fuel gas consumed by the propulsion engine 40 by the set load of the propulsion engine 40 to the fuel control device 62a of the pressurization control device 62. The gas load signal ACL is a signal representing (injection rate of fuel gas per rotation of the propulsion engine 40) / (actual rotation number of the engine 40) / (normal maximum rotation number of the propulsion engine 40). Here, the fuel gas injection rate is the ratio of the current injection amount when the injection amount of fuel gas per rotation is 100% when the load on the propulsion engine 40 is 100%.
The ECU 60 sends the set information of the opening / closing of the opening / closing valve 66 to the opening / closing valve control device 62b of the pressurization control device 62.

The control integration device 62c (see FIG. 1) sets a result obtained by adding a constant (constant) pressure to the required pressure of the fuel gas sent to the control integration device 62c as the set pressure Sv. The reason for adding a constant (constant) pressure (α) to the required pressure (required pressure + α) is that the pressure may decrease at the pressure control valve 64 or the opening / closing valve 66. This is because the required pressure of the fuel gas required by the propulsion engine 40 may not be satisfied.
When the amount of pressure decrease at the pressure control valve 64 or the opening / closing valve 66 changes according to the gas load signal ACL of the propulsion engine 40, according to one embodiment, the control integration device 62c sets the required pressure to be constant (constant). ), It is also preferable to calculate an additional pressure according to a predetermined function with respect to the gas load signal ACL, and to add this additional pressure to the required pressure instead of the constant pressure (α). .
In FIG. 1, the illustration of the configuration for adding the pressure to the required pressure is omitted.

The pressurization control device 62 includes a fuel control device 62a, an opening / closing valve control device 62b, and a control integration device 62c.
FIG. 4 is a control block diagram of an example of control performed by the pressurization control device 62.

The fuel control device 62a controls a feed-forward control signal that controls the amount of boil-off gas delivered from the pressurizing device 30 based on a change in the gas load signal ACL indicating the amount of fuel gas consumed by the propulsion engine 40. Generate FFw. The generation of the control signal FFw is performed when the fluctuation of the gas load signal ACL is out of a predetermined range. Specifically, the control signal FFw is generated using the FFw function stored and held by the fuel control device 62a with respect to the fluctuation of the gas load signal ACL. The fluctuation of the gas load signal ACL is a time change of the gas load signal ACL sequentially transmitted from the ECU 60 at a predetermined clock. When this time change is out of the predetermined range (the fluctuation of the gas load signal ACL is large), the fuel control device 62a greatly deviates the pressure measured by the pressure gauge 38e from the set pressure Sv of the fuel gas.
In the example shown in FIG. 4 , the set pressure Sv is a pressure (required) obtained by adding a constant (constant) pressure (α) to the required pressure in consideration of the amount of pressure reduction at the pressure control valve 64 or the opening / closing valve 66. Pressure + α). For this reason, when the time change of the gas load signal ACL in the propulsion engine 40 deviates from the predetermined range, the pressure of the boil-off gas in the main pipe 31 of the pressurizing mechanism 30 is not largely changed from the set pressure Sv of the fuel gas. The fuel control device 62a controls the amount of boil-off gas delivered from the pressurizing mechanism 30 according to the change in the amount of fuel supply.

  The fuel control device 62a calculates, for example, using the gas load signal ACL of the propulsion engine 40 and the FFw function, further multiplies it by a predetermined correction coefficient, and expresses the value as an adjustment amount of the opening degree of the adjustment valve 34e. The control signal FFw is generated. The generated control signal FFw is sent to the control integration device 62c. The correction coefficient will be described later. Although the fuel control device 62a of the present embodiment calculates the control signal FFw using the FFw function, according to one embodiment, the relationship between the change in the gas load signal ACL and the adjustment amount of the opening of the adjustment valve 34e is determined in advance. The indicated reference table may be stored, and the control signal FFw may be generated by referring to the reference table from the gas load signal ACL sent.

  The opening / closing valve control device 62b controls the boil-off gas based on the change of the opening / closing valve 66 provided in the propulsion engine 40 from ON (fully open) to OFF (completely closed) or OFF (completely closed) to ON (fully open). A control signal FFv for feedforward control for controlling the transmission amount is generated. Specifically, when changing the type of fuel supplied to the propulsion engine 40 from boil-off gas to oil such as heavy oil from a state in which the propulsion engine 40, which is a dual fuel engine, is driven using boil-off gas, The on-off valve 66 is rapidly closed. In this case, since the boil-off gas is prevented from flowing from the on-off valve 66 to the pipe on the propulsion engine 40 side, the pressure on the main pipe 31 on the upstream side of the on-off valve 66 and the pressure on the delivery side of the compression mechanism 30 suddenly increase. It rises to an abnormal pressure.

When the type of fuel supplied to the propulsion engine 40 is changed from oil such as heavy oil to boil-off gas, the on-off valve 66a is rapidly opened. In this case, the pressure of the main pipe 31 on the upstream side of the opening / closing valve 66 and the pressure on the delivery side of the compression mechanism 30 rapidly decrease. Due to this sudden decrease, the propulsion engine 40 does not instantaneously exhibit sufficient output.

Therefore, the opening / closing valve control device 62b performs feedforward control for controlling the amount of boil-off gas delivered based on the information V of the change from ON to OFF or from OFF to ON of the opening / closing valve 66 provided in the propulsion engine 40. Therefore, the control signal FFv is generated. The generated control signal FFv is sent to the control integration device 62c.
The on-off valve control device 62b calculates using, for example, information V of the change of the on-off valve 66 and the FFv function stored and held by the on-off valve control device 62b, and further multiplies the correction value by a predetermined correction coefficient. It is generated as a control signal FFv expressed as an adjustment amount of the opening degree of the adjustment valve 34e. Specifically, a control signal FFv that increases or decreases the amount of boil-off gas delivered by a certain amount is generated. The correction coefficient will be described later.
The opening / closing valve control device 62b of the present embodiment generates the control signal FFv using the FFv function. According to one embodiment, the relationship between the on / off information V and the adjustment amount of the opening degree of the adjustment valve 34e is determined in advance. It is also preferable to store a reference table indicating the control signal FFv by referring to the reference table from the information V.
When the open / close valve 66 is configured by a gas valve train including a plurality of valves and a flow path, according to one embodiment, the on / off operation is performed for each valve, and further, for each valve that is opened. Preferably, the control signal FFv is generated such that the above-described feedforward control is performed.

Integrated control unit 62c, the control signal FFW, FFv and, combined into one control signal FFB control signals FBp for feeds back control to be described later is generated by the integrated control device 62c for the two feedforward control This is a device for sending to the adjustment valve 34e of the pressurizing mechanism 30.
The control integration device 62c controls the amount of fuel delivered from the compression mechanism 30 based on the difference between the set pressure Sv of the propulsion engine 40 and the measured pressure Pv of the fuel in the main pipe 31 on the delivery side of the compression mechanism 30. A control signal FBp for control is generated. The value of the control signal FBp is expressed as an adjustment amount of the opening of the adjustment valve 34e.
The measured pressure Pv is a pressure measured by the pressure gauge 38e, and is sent to the control integration device 62c. The set pressure Sv refers to a pressure (required pressure + α) determined based on a required pressure of fuel required for the propulsion engine 40. The required pressure is set low, for example, at a low load and high at a high load. Such a required pressure is set in advance according to the propulsion engine 40, and is stored in the ECU 60.
The control integration device 62c generates, for example, a difference between the measured pressure Pv and the set pressure Sv as a control signal FBp for feedback control using PID control.
According to one embodiment, the control integration device 62c stores in advance a reference table indicating the relationship between the difference between the set pressure Sv and the measured pressure Pv and the amount of adjustment of the opening of the adjustment valve 34e. It is also preferable to generate the control signal FBp by referring to the reference table from the difference between the measured pressures Pv.

The control integration device 62c adds the control signal FFw sent from the fuel control device 62a, the control signal FFv sent from the opening / closing valve control device 62b, and the control signal FBp generated by the control integration device 62c. One control signal FFB is collected and sent to the adjustment valve 34e of the pressurizing mechanism 30. By controlling the pressure of the boil-off gas in this manner, the amount of boil-off gas delivered by the compression mechanism 30 can be controlled. Further, the control integration device 62c controls the opening degree of the adjustment valve 34 by PID control based on the measured pressure Pv sent from the pressure gauge 38e. In this control, a control signal for controlling the opening of the adjustment valve 34e is generated and sent to the adjustment valve 34e so that the pressure Pv measured by the pressure gauge 38 falls within a predetermined range.
As described above, the opening degree of the adjustment valve 34e provided in the bypass pipe 33e of the gas compressor 32e provided at the most downstream stage of the multistage gas compressor and maximizing the boil-off gas pressure is controlled by the feedforward control and the feedback control. To control. This makes it possible to most effectively suppress fluctuations in the pressure of the fuel to be supplied in response to a sudden change in the load of the propulsion engine 40 and a sudden change in the pressure with respect to the on / off of the on-off valve 66.

Further, although not shown in FIG. 3, according to one embodiment, the control integration device 62c includes the control signals FFw and FFv for the two feedforward controls and the measured pressures measured by the pressure gauges 38a to 38d. It is also preferable that control signals based on the PID control generated based on the difference between the control signal and the preset target pressure be sent to the adjustment valves 34a to 34d of the pressurizing mechanism 30 as one control signal. Further, in a multi-stage pressurizing mechanism in which a plurality of sets including the gas compressors 32a to 32e, the bypass pipes 33a to 33e, and the adjustment valves 34a to 34e are provided in series, the pressurizing control device 62 includes: It is preferable to control the opening degree of each of the plurality of sets of adjustment valves 34a to 34e using a feedforward control signal obtained by adding the control signal FFw and the control signal FFv, thereby controlling the amount of fuel delivered.
Thus, the amount of boil-off gas delivered by the pressurizing mechanism 30 can be controlled more efficiently. In particular, it is possible to suppress the pressure in the pressurizing mechanism 30 from becoming an abnormal pressure in response to a sudden change in the load of the propulsion engine 40 or a sudden change in the pressure with respect to the on / off of the on-off valve 66, and stable pressurization. Can be maintained.

  As described above, in the control of the fuel delivery amount of the pressurizing mechanism 30 performed by the pressurizing control device 62, the on-off valve 66 is turned on (fully closed) to off (completely closed) or off (completely closed) to on (fully opened). ) Includes feedforward control for controlling the amount of fuel delivered based on the change to (2). Therefore, when switching the type of fuel using a dual fuel engine, the on-off valve 66 is turned on / off. However, a rapid change in the pressure of the fuel supplied to the propulsion engine 40 can be suppressed.

In the present embodiment, as shown in FIG. 4, the control signal FFw, the control signal FFv, and the control signal FBp are added to one control signal FFB, and the control signal FFB is sent to the adjustment valve 34e to be adjusted. The opening of the valve 34e is controlled. According to one embodiment, as shown in FIG. 5, the control integration device 62c selects one of a control signal obtained by adding the control signal FFw and the control signal FBp and a fixed value (constant value) control signal. A switch 62d may be provided for switching the control signal, and the control signal selected by the switch 62d may be sent to the adjustment valve 34e. FIG. 5 is a control block diagram illustrating an example of control performed by the pressurization control device 62 according to the embodiment.
In this case, the selection of the control signal in the switch 62d is performed based on the information V on the change of the open / close valve 66, which is a control signal from the ECU 60. Specifically, when the information V is information for closing the on-off valve 66, the switch 62d selects a control signal of a fixed value (constant value), and when the information V is information for opening the on-off valve 66, Reference numeral 62d selects a control signal obtained by adding the control signal FFw and the control signal FBp. When the on-off valve 66 is closed, boil-off gas is not supplied from the pressurizing mechanism 30 to the propulsion engine 40 as fuel gas. At this time, since the opening of the control valve 34e is constant such that the pressure of the discharge snubber 36e is constant, the switch 62d selects a fixed value (constant value) control signal. The fixed value of the control signal is set so that the pressure of the discharge snubber 36e is constant.

The pressurization control device 62 preferably controls the fuel delivery amount such that the control amount of the fuel delivery amount from the pressurizing mechanism 30 is adjusted according to the set pressure Sv. As shown in FIG.
The control signal FFw is corrected by multiplying the feedforward control signal FFw generated by the fuel control device 62a by a correction coefficient determined in accordance with the set pressure Sv sent from the control integration device 62c to the fuel control device 62a. Further, the control signal FFv is corrected by multiplying the control signal FFv of the feedforward control by the open / close valve control device 62b by a correction coefficient determined in accordance with the set pressure Sv sent from the control integration device 62c to the open / close valve control device 62b. I do.

FIG. 6 is a diagram illustrating an example of the relationship between the correction coefficient and the set pressure Sv. That is, if the set pressure Sv decreases, the correction coefficient may be reduced.
If the pressure of the fuel in the main pipe 31 is different, the operation of the pressurizing mechanism 30 may be different even when the amount of the delivered fuel is changed by the same amount. When the pressurizing mechanism 30 is a multi-stage gas compressor and the control of the fuel pressure at the time of sending out the boil-off gas of the pressurizing mechanism 30 is performed by the adjusting valve 34e provided in the bypass pipe 33e, the pressure of the boil-off gas to be pressurized is increased. When the pressure is different, the opening degree of the regulating valve 34e for changing the flow rate by the same amount is greatly different. In order to realize more stable control, the amount of boil-off gas (fuel) delivered is changed by changing the correction coefficient by which the control signals FFw and FFv are multiplied according to the set pressure Sv of the propulsion engine 40 in order to correct this difference. Is preferably adjusted.

  Further, the control of the amount of fuel delivered from the pressurizing mechanism 30 may be performed by controlling the number of rotations of a drive source for driving the gas compressors 32a to 32e. The pressure control device 62 controls the amount of fuel such as boil-off gas delivered from the pressurizing mechanism 30 by controlling all the opening degrees of the adjustment valves 34a to 34e. This is preferable because it can be easily performed.

  By using such a fuel gas supply system 10, a fuel gas supply method as described below can be performed.

That is, when supplying fuel gas to the plurality of propulsion engines 40, the fuel gas supply system 10
(A) In order to supply the boil-off gas vaporized from the tank 20 storing the liquefied gas to the propulsion engine 40 as a fuel gas, the boil-off gas or the liquefied gas vaporized from the liquefied gas is pressurized and sent out by the pressurizing mechanism 30 as fuel. Steps and
(B) The amount of fuel delivered by the pressurizing mechanism 30 is fed back based on the difference between the set pressure Sv determined based on the required fuel pressure required by the propulsion engine 40 and the measured pressure Pv of the pressurized fuel. Controlling; and
(C) performing feedforward control of the delivery amount based on a change in the gas load signal ACL indicating the fuel gas consumption amount of the propulsion engine 40. At this time, the feedforward control is performed when the fluctuation of the gas load signal ACL of the propulsion engine 40 is out of the predetermined range.

Further, feedforward control for controlling the amount of fuel delivered by the pressurizing mechanism 30 based on a change from on to off or from off to on of an on-off valve 66 for turning on / off the supply of fuel gas to the propulsion engine 40. A.
In the control of the fuel delivery amount by the pressurizing mechanism 30, the control amount of the fuel delivery amount is adjusted according to the set pressure Sv.
Further, the control of the fuel delivery amount by the pressurizing mechanism 30 is performed by controlling the flow rate of the fuel flowing through each of the bypass pipes 33a to 33e.

  As described above, the fuel gas supply system, the fuel gas supply method, and the ship according to the present invention have been described in detail. However, the present invention is not limited to the above embodiment, and various improvements and modifications may be made without departing from the gist of the present invention. Of course, you can do it.

Reference Signs List 10 fuel gas supply system 20 tank 30 pressurizing mechanism 31 main pipes 32a to 32e gas compressors 33a to 33e bypass pipes 34a to 34e adjustment valves 35a to 35e suction snubbers 36a to 36e discharge snubbers 37a to 37e heat exchanger 38 check valve 38a 38e, 65a, 65b Pressure gauge 40 Propulsion engine 42 Tachometer 45 Main shaft 46 Propeller 50 Liquefaction device 60 Engine control unit 61 Pressure controller 62 Pressurization control device 62a Fuel control device 62b Open / close valve control device 62c Control integration device 64 Pressure control Valve 66 Open / close valve 70 Gas treatment device

Claims (11)

A fuel gas supply system that supplies fuel gas to an engine,
A tank for storing liquefied gas,
A pressurizing mechanism that pressurizes and sends out the boil-off gas or the liquefied gas vaporized from the liquefied gas as fuel to supply the boil-off gas vaporized from the liquefied gas to the engine as a fuel gas,
A pressure control device for controlling the delivery amount of the fuel that the pressure mechanism is sent,
Connecting said engine and said pressurizing mechanism, the pressurizing mechanism is the fuel is sent and a main pipe flowing through the engine,
The control of the delivery amount performed by the pressurization control device, the transmission amount based on the difference between the measured pressure of the fuel demand set pressure determined based on the required pressure of the fuel to be in the main pipe of the engine a feedback control for controlling a feedforward control time variation of the gas load signal indicating an amount of consumption of the fuel gas of the engine to control the transmission amount based on the time change when it becomes larger out of the predetermined range , A fuel gas supply system comprising: A fuel gas supply system that supplies fuel gas to an engine,
A tank for storing liquefied gas,
A pressurizing mechanism that pressurizes and sends out the boil-off gas or the liquefied gas vaporized from the liquefied gas as fuel to supply the boil-off gas vaporized from the liquefied gas to the engine as a fuel gas,
A pressurization control device that controls a delivery amount of the fuel that the pressurization mechanism delivers,
A main pipe that connects the pressurizing mechanism and the engine, and in which the fuel delivered by the pressurizing mechanism flows to the engine,
The control of the delivery amount performed by the pressurization control device is performed based on a difference between a set pressure determined based on a required pressure of the fuel required by the engine and a measured pressure of the fuel in the main pipe. Feedback control that controls the amount of fuel gas consumed by the engine, and feed forward control that controls the delivery amount based on a change in a gas load signal indicating the consumption amount of the fuel gas,
The main Piping, closing valve is provided to supply the ON / OFF of the fuel gas to the engine,
The control of the delivery rate of the pressure control device performs further on the basis of the information changes from the on-off valve from OFF to ON or OFF, comprising a feed-forward control for controlling the delivery rate, the Characteristic fuel gas supply system.   The fuel gas supply system according to claim 1, wherein the pressurization control device controls the delivery amount such that the control amount of the delivery amount is adjusted according to the set pressure. The pressurizing mechanism includes a pressure device for pressurizing the fuel, a bypass pipe between piping the said fuel after before pressurization by the pressurizing device flows, connected to bypass the pressurizing device, the bypass A regulating valve for controlling the amount of said fuel flowing through the tube;
The fuel gas supply according to any one of claims 1 to 3, wherein the pressurization control device controls the delivery amount by controlling an opening degree of the adjustment valve using the feedforward control. system. The pressurizing mechanism includes a pressure device for pressurizing the fuel, a bypass pipe between piping the said fuel after before pressurization by the pressurizing device flows, connected to bypass the pressurizing device, the bypass A plurality of sets comprising a regulating valve for controlling the amount of the fuel flowing through the pipe, a multi-stage pressurizing mechanism provided in series,
The pressurization control device according to any one of claims 1 to 3, wherein the plurality of sets of respective adjustment valves are controlled by using the feedforward control to control the delivery amount. A fuel gas supply system as described. A fuel gas supply system according to any one of claims 1 to 5,
A propulsion engine driving using the fuel pressurized by the pressurizing mechanism,
And a control unit for controlling the propulsion engine. A fuel gas supply method for supplying fuel gas to an engine,
In order to supply the boil-off gas vaporized from the tank storing the liquefied gas as a fuel gas to a plurality of engines, pressurizing and sending the boil-off gas vaporized from the liquefied gas or the liquefied gas as fuel,
A step of feedback controlling the delivery amount of the fuel based on the difference between the measured pressure set pressure and pressurized the fuel determined based on the required pressure of the fuel required by the said engine,
And a step of feed-forward controlling the transmission amount based on the time variation of the gas load signal indicating an amount of consumption of the fuel gas of the engine,
The fuel gas supply method according to claim 1, wherein the feedforward control is performed when a time change of the gas load signal becomes larger than a predetermined range. A fuel gas supply method for supplying fuel gas to an engine,
In order to supply the boil-off gas vaporized from the tank storing the liquefied gas as a fuel gas to a plurality of engines, pressurizing and sending the boil-off gas vaporized from the liquefied gas or the liquefied gas as fuel,
Feedback controlling the delivery amount of the fuel based on the difference between the set pressure determined based on the required pressure of the fuel required by the engine and the measured pressure of the fuel pressurized,
Feedforward controlling the delivery amount based on a change in a gas load signal indicating the fuel gas consumption amount of the engine,
The feedforward control is performed when the fluctuation of the gas load signal is out of a predetermined range,
Further comprising the based on a change from ON of the switching valve for supplying the on / off of the fuel gas from off to on or off, the step of the feed-forward control for controlling the delivery rate to each engine, it A fuel gas supply method comprising:   9. The fuel gas supply method according to claim 7, wherein in the control of the delivery amount, the control amount of the delivery amount is adjusted according to the set pressure. Pressurization and delivery of the fuel is carried out at a pressure mechanism,
The pressurizing mechanism includes a pressure device for pressurizing the fuel, between piping the flow the fuel after before pressurization by the pressurizing device, a bypass tube connected to bypass the pressure device, the ,
Control of the delivery amount, the flow rate of the fuel flowing through the bypass pipe, the is performed by controlling with the feed-forward control, the fuel gas supply method according to any one of claims 7-9. Pressurization and delivery of the fuel is carried out at a pressure mechanism,
The pressurizing mechanism comprises a pressurizing device for pressurizing the fuel, between piping the flow the fuel after before pressurization by the pressurizing device, a bypass tube connected to bypass the pressure device, the It is a multi-stage pressurizing mechanism provided with a plurality of sets, which are provided in series.
The delivery amount of control, the flow rate of the fuel flowing through the bypass pipe of the plurality of pairs each, the is performed by controlling with the feedforward control, according to any one of claims 7-9 Fuel gas supply method.

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