JP6551684B2 - Fuel gas supply system and fuel gas supply method - Google Patents

Description

  The present invention relates to a fuel gas supply system and a fuel gas supply method for supplying fuel gas to a propulsion engine of a ship.

  In the LNG carrier, a boil-off gas in which the liquefied natural gas is naturally vaporized is generated in the LNG tank storing the liquefied natural gas. The boil-off gas is supplied as a fuel gas to a propulsion engine of a ship.

In order to use a low-pressure fluid such as boil-off gas as a high-pressure fluid, the boil-off gas is compressed using a multistage compressor. A multistage compressor consists of several compressors connected in series, for example (patent document 1).
Furthermore, it is also known that the boil-off gas is pressurized to about 30 MPa using a multistage gas compressor and supplied to a gas injection valve of an engine (MC-GI engine) (Non-Patent Document 1).

Japanese Patent Application Laid-Open No. 8-219088

"Achievements of Large Gas Injection Diesel Engine (MC-GI Engine)", Tetsugo Fukuda et al., Journal of the JIME Vol.36, No.9, pp.64-70

The above-mentioned engine (MC-GI engine) is an engine for land power generation, and is basically a low-speed diesel engine on the premise of substantially constant load operation, and multi-stage gas compressors may also supply substantially constant fuel gas .
On the other hand, when such a multistage gas compressor is applied to a low speed diesel engine for ship propulsion, the load of this engine changes with time, so the operation of the multistage compressor also needs to change. For example, when reducing the load on the engine and further stopping it, the pressure of the fuel gas tends to be high on the downstream side in the fuel gas supply direction, because less fuel gas is used or it becomes zero. In this case, the pressure of the fuel gas in the discharge snubber provided accompanying the gas compressor is lower than the pressure of the fuel gas in the suction snubber provided accompanying the other gas compressor located downstream of the discharge snubber. In some cases, the fuel gas flows backward from the downstream suction snubber to the upstream discharge snubber through the gas supply line.

  In addition, when the multistage gas compressor is restarted from the stop, if the pressure of the fuel gas in the suction snubber and the discharge snubber attached to the gas compressor is stopped in the same state, the suction snubber is driven by the driving of the gas compressor. It takes a long time to produce a pressure difference between the fuel gas in the discharge snubber and supply the fuel gas constantly. Therefore, in order to reduce the time until the fuel gas can be supplied to the engine in a steady state, stop with the pressure of the fuel gas in the discharge snubber increased with respect to the suction snubber attached to the gas compressor. Is preferred. However, such a fuel gas supply system is not known.

  Therefore, the present invention provides a fuel gas capable of preventing the fuel gas from flowing backward between the multistage compression mechanisms when the supply of the fuel gas pressurized using the multistage compression mechanism to the engine is stopped. Supply system, fuel gas supply method, and fuel gas supply system and fuel gas supply method capable of realizing stable supply of fuel gas from the multistage compression mechanism to the engine in a short time when the compression mechanism is restarted Intended to provide.

One aspect of the present invention is a fuel gas supply system for supplying a fuel gas to a propulsion engine of a ship. The fuel gas supply system
A fuel gas source;
A plurality of compression mechanisms provided in series with a gas supply line for supplying fuel gas supplied from the fuel gas source to a propulsion engine of a ship, and compressing the fuel gas and flowing it to the side of the propulsion engine; .
Each of the compression mechanisms is provided upstream of the gas compressor in the supply direction of the fuel gas to the propulsion engine so as to be associated with the gas compressor for compressing the fuel gas and the gas compressor, and the gas A low pressure gas flow path for supplying the fuel gas toward a compression chamber of a compressor, and the fuel gas provided downstream of the gas compressor in the supply direction, and promoting the fuel gas compressed in the compression chamber of the gas compressor A high-pressure gas flow path that is supplied to the engine, a bypass pipe that connects the low-pressure gas flow path and the high-pressure gas flow path without passing through the compression chamber, and a flow rate of the fuel gas in the bypass pipe is controlled. a control valve for the flow of said fuel gas, allowing both directions of flow between the compression chamber and the low-pressure gas passage An unloader capable of switching between an unloading state and a loading state in which the flow of the fuel gas is restricted from the low pressure gas passage to the flow in one direction from the low pressure gas passage, and a control unit for controlling the operation of the unloader And comprising
A check valve for preventing the fuel gas from flowing backward in the reverse direction of the supply direction is provided in each of the gas supply lines connecting the plurality of compression mechanisms ,
The control unit sends a control signal for switching from the load state to the unload state to the unloader before the operation of the gas compressor is stopped .

Another aspect of the present invention is a fuel gas supply method using a fuel gas supply system that supplies fuel gas to a marine propulsion engine.
The fuel gas supply system
A fuel gas source,
A plurality of compression mechanisms provided in series with a gas supply line for supplying fuel gas supplied from the fuel gas source to a propulsion engine of a ship, and compressing the fuel gas and flowing it to the side of the propulsion engine; .
Each of the compression mechanisms is provided on the upstream side of the gas compressor in the supply direction of the fuel gas to the propulsion engine so as to be associated with the gas compressor for compressing the fuel gas and the gas compressor, A low pressure gas flow path for supplying the fuel gas toward the compression chamber of the gas compressor, and the fuel gas provided downstream of the gas compressor in the supply direction and compressed in the compression chamber of the gas compressor A high pressure gas flow path for supply to a propulsion engine, a bypass pipe connecting the low pressure gas flow path and the high pressure gas flow path without passing through the compression chamber, and a flow rate of the fuel gas in the bypass pipe And a control valve to control.
In the fuel gas supply method, when the operation of the gas compressor is stopped,
Each of the compression mechanisms is configured to restrict the flow of the fuel gas from the loaded state in which the flow of the fuel gas is restricted to the flow in one direction from the low pressure gas passage to the compression chamber; Switching to an unloaded condition allowing bi-directional flow to and from the compression chamber;
Due to the unloading state, the fuel gas in the high-pressure gas passage flows into the low-pressure gas passage through the bypass pipe, and the pressure in the high-pressure gas passage is reduced. Preventing a back flow of the fuel gas from one low pressure gas flow path of the compression mechanism located in a direction opposite to the supply direction;
Closing the control valve to prevent the flow rate of the fuel gas in the bypass pipe while preventing the reverse flow; and
Stopping the operation of the gas compressor after setting the flow rate of the fuel gas to zero.

When starting the operation of the gas compressor from the stop of the operation of the gas compressor,
Starting the operation of the gas compressor with the control valve closed and the unload condition;
And opening the control valve when the operation of the gas compressor is in a steady state, and switching from the unload state to the load state.

Yet another embodiment of the present invention is also a fuel gas supply method using a fuel gas supply system that supplies fuel gas to a propulsion engine of a ship.
The fuel gas supply system
A fuel gas source,
A plurality of compression mechanisms provided in series with a gas supply line for supplying fuel gas supplied from the fuel gas source to a propulsion engine of a ship, and compressing the fuel gas and flowing it to the side of the propulsion engine; .
Each of the compression mechanisms is provided on the upstream side of the gas compressor in the supply direction of the fuel gas to the propulsion engine so as to be associated with the gas compressor for compressing the fuel gas and the gas compressor, A low pressure gas flow path for supplying the fuel gas toward the compression chamber of the gas compressor, and the fuel gas provided downstream of the gas compressor in the supply direction and compressed in the compression chamber of the gas compressor A high pressure gas flow path for supply to a propulsion engine, a bypass pipe connecting the low pressure gas flow path and the high pressure gas flow path without passing through the compression chamber, and a flow rate of the fuel gas in the bypass pipe And a control valve to control.
Each of the compression mechanisms is in an unloaded state allowing flow of the fuel gas in both directions between the low pressure gas flow path and the compression chamber during cessation of operation of the gas compressor, and The control valve is in a closed state, and starting the operation of the gas compressor in the unloaded state and the closed state;
The fuel gas supply method includes a step of opening the control valve and switching from the unload state to the load state when the operation of the gas compressor reaches a steady state.

  While the operation of the gas compressor is stopped, it is preferable that the pressure of the high pressure gas flow path of each of the compression mechanisms of the fuel gas supply system is maintained higher than the pressure of the low pressure gas flow path. .

  According to the fuel gas supply system and the fuel gas supply method of the above aspect, backflow of the fuel gas can be prevented between the multistage compression mechanisms. In addition, stable supply of fuel gas from the multistage compression mechanism to the engine can be realized in a short time.

It is a figure which shows an example of a structure of the fuel gas supply system of this embodiment. It is a figure explaining the discharge amount of the boil off gas of the gas compressor of this embodiment, and the flow volume of the boil off gas which flows through a bypass pipe in the upstream direction. It is a figure which shows the structure of an example of the non-return valve and unloader of this embodiment. (A), (b) is a figure explaining an example of the non-return valve used by the fuel gas supply system of this embodiment, and an unloader. It is a figure explaining the flow of an example of the fuel gas supply method of this embodiment. It is a figure explaining the flow of another example of the fuel gas supply method of this 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. Although liquefied natural gas is used as the liquefied gas of the fuel gas supply system 10, it is not limited to liquefied natural gas, and pure methane gas, pure ethane gas, or the like can be used. The boil-off gas includes, in addition to the gas vaporized by natural heat input in the tank, gas that is forcibly vaporized by intentionally heating LNG.

  The fuel gas supply system 10 is used to supply boil-off gas vaporized in the LNG tank 12 storing liquefied natural gas to the propulsion engine 14 as fuel gas in an LNG carrier carrying liquefied natural gas. The LNG tank 12 is a fuel gas source. In this embodiment, the direction in which the boil-off gas is supplied from the LNG tank 12 to the propulsion engine 14 is referred to as the downstream direction, the opposite direction is referred to as the upstream direction, and the downstream side from the reference position is referred to as the downstream side. The upstream side from the reference position is called the upstream side.

The fuel gas supply system 10 according to the present embodiment pressurizes the fuel gas to supply the fuel gas to the propulsion engine 14 that propels the ship upon receiving the supply of the fuel gas, and the propulsion engine 14 is viewed from the LNG tank 12 side. A plurality of gas compression mechanisms 13a to 13e to be flowed to the side of The plurality of gas compression mechanisms 13a to 13e are provided in series on the gas supply line.
The gas compression mechanisms 13a to 13e include gas compressors 16a to 16e, suction snubbers 18a to 18e, discharge snubbers 20a to 20e, heat exchangers 22a to 22e, bypass pipes 24a to 24e, control valves 26a to 26e, The control devices 28a to 28e and check valves 34a to 34e with check valves 32a to 32e (see FIGS. 3, 4A, and 4B) are mainly provided. Check valves 32a to 32e are provided in gas supply lines that connect the gas compression mechanisms 13a to 13e.

The LNG tank 12 stores liquefied natural gas which is a cargo transported by the LNG carrier. Here, natural gas is hydrocarbon gas, which is a fossil fuel produced naturally, or a gas produced from a crude oil refining plant, and includes carbon compounds such as methane, ethane, propane and the like. Liquefied natural gas (LNG) is a natural gas cooled and liquefied. Although a spherical tank is illustrated in FIG. 1, the present embodiment is not limited to this, and a membrane tank may be used.
As used herein, “boil-off gas” refers to natural gas vaporized in the LNG tank 12, but also includes vaporized liquefied natural gas outside the LNG tank 12. Although the ship to which the present embodiment is applied is an LNG ship, it is also possible to store liquefied natural gas in a tank, pressurize the boil-off gas, and apply it to the engine as fuel gas to supply it to the engine. it can.

The propulsion engine 14 uses the supplied boil-off gas as fuel gas to burn in the combustion chamber to extract power, and rotates the main shaft 15a and the propeller 15b. For the propulsion engine 14, for example, a low-speed diesel engine with a two-stroke cycle can be used.
The propulsion engine 14 is connected to the governor 15c and its drive is controlled. The governor 15c is provided on a supply line for supplying the fuel gas to the propulsion engine 14 so that the main spindle rotational speed measured by the tachometer 15d provided to measure the rotation of the main spindle 15a becomes the target rotational speed. The drive of the propulsion engine 14 is controlled by controlling the opening of a flow control valve (not shown). That is, the governor 15c determines the load of the propulsion engine 14 so that the main spindle rotational speed of the main spindle 15a connecting the propulsion engine 14 and the propeller 15b for propulsion becomes the target rotational speed, and the fuel supply of fuel gas It is a device that controls the quantity. The governor 15c determines the load of the propulsion engine 14 so that the main spindle rotational speed is maintained at the target rotational speed even if the natural conditions of weather, sea-like wind and wave height change, and the operator's deceleration, acceleration, turning The load of the propulsion engine 14 can also be determined according to the operation command value of the propeller rotation speed provided by such an instruction. The governor 15c is configured to set a target pressure on the discharge side of the gas compressor 16e located at the most downstream position based on the determined load, and to send the target pressure to the control device 28e. This target pressure is the fuel supply pressure required by the propulsion engine 14.

The gas compressors 16a to 16e are multistage compressors connected in series on a gas supply line that compresses boil off gas generated in the LNG tank 12 as fuel gas and supplies the compressed fuel gas to the propulsion engine 14. The gas compressors 16a to 16e are portions that pressurize the fuel gas supplied from the suction snubbers 18a to 18e. The gas compressors 16a to 16e may be, for example, reciprocating compressors in which the movable parts (plungers or pistons) in the gas compressors 16a to 16e linearly reciprocate to suck gas and then compress the gas. Among the gas compressors 16a-16e, an oil-free compressor is used as the gas compressors 16a-16d, and a feed-type compressor is used as the gas compressor 16e that pressurizes the fuel gas to a high pressure. The movable parts of the gas compressors 16a to 16e are driven in conjunction with each other via a crankshaft that is rotated by the power of a drive source (not shown) (for example, an electric motor) described above. In the gas compressors 16a to 16e, the fuel gas is compressed stepwise at the same compression rate, so that the fuel 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 16a to 16e, the fuel gas is compressed to ³ 5-4 ⁵ times. For example, if the pressure of the fuel gas on the suction side of the gas compressor 16a is 0.1 MPa, the pressure on the discharge side of the gas compressor 16a is about 0.39 MPa, the pressure on the discharge side of the gas compressor 16b is about 1.24 MPa, the gas The pressure on the discharge side of the compressor 16c is about 4.00 MPa, and the pressure on the discharge side of the gas compressor 16d is about 11.3 MPa. Then, the pressure on the discharge side of the gas compressor 16e is increased to the set target pressure.

The suction snubbers 18a to 18e are provided in association with the gas compressors 16a to 16e, respectively, and temporarily store fuel gas before compression, which is provided upstream of the gas compressors 16a to 16e, and further, the gas compressors 16a to 16e A container for supplying fuel gas to the compression chamber of That is, the suction snubbers 18a to 18e constitute a low-pressure gas passage that supplies fuel gas toward the compression chambers of the gas compressors 16a to 16e. Accordingly, the pressure in the suction snubbers 18a to 18e corresponds to the pressure of the fuel gas immediately before being pressurized by the gas compressors 16a to 16e.
The discharge snubbers 20a to 20e are provided in association with the gas compressors 16a to 16e, respectively, and temporarily store compressed fuel gas provided downstream of the gas compressors 16a to 16e, respectively, and are directed to the propulsion engine 14 Is a container for supplying fuel gas. The discharge snubbers 20a to 20e are provided with pressure gauges 19a to 19e for measuring the pressure of the fuel gas stored inside. The measurement results of the pressure gauges 19a to 19e are sent to control devices 28a to 28e described later. The suction snubbers 18a to 18e and the discharge snubbers 20a to 20e are provided with safety valves (not shown) that open the valves with a predetermined pressure.

The heat exchangers 22a to 22e are devices for cooling the fuel gas, which has become high temperature by compression of the fuel gas by each of the gas compressors 16a to 16e, to a predetermined temperature by exchanging heat with a refrigerant. Although it does not restrict | limit especially as a refrigerant | coolant, The cold boil-off gas immediately after produced | generated with the LNG tank 12 can be used. The heat exchangers 22a to 22d are connected to suction snubbers 18b to 18e located on the downstream sides of the heat exchangers 22a to 22d through gas supply lines.
The discharge snubbers 20a to 20e and the heat exchangers 22a to 22e constitute a high pressure gas flow path for supplying the fuel gas compressed in the compression chambers of the gas compressors 16a to 16e to the propulsion engine 14.

  As will be described later, the check valves 32a to 32e are provided to prevent the fuel gas from flowing backward in the upstream direction when the gas compressors 16a to 16e are stopped or restarted.

Bypass pipes 24a to 24e are provided between suction snubbers 18a to 18e attached to the gas compressors 16a to 16e, respectively, and high pressure gas flow paths connecting the heat exchangers 22a to 22e and the check valves 32a to 32e. It has been. The bypass pipes 24a to 24e connect the low pressure gas flow path and the high pressure gas flow path, and from the gas output portion on the downstream side of the heat exchangers 22a to 22e which are high pressure gas flow paths, suction snubbers 18a to 18e which are low pressure gas flow paths. The pressurized fuel gas is allowed to flow toward the The flow from the downstream side to the upstream side of the fuel gas is called backflow.
The bypass pipes 24a to 24e are provided with control valves 26a to 26e for controlling the amount of fuel gas flowing.

  FIG. 2 is a diagram for explaining the discharge amount of the fuel gas discharged from the gas compressors 16a to 16e in the downstream direction and the flow rate of the fuel gas flowing backward through the bypass pipes 24a to 24e in the upstream direction. Although the flow of the second stage gas compressor 16 b and the bypass pipe 24 b is described in FIG. 2, the same behavior is performed in the other gas compressors and the bypass pipe. As shown in FIG. 2, for example, when 1500 kg of fuel gas is supplied from the upstream side per hour, and the gas compressor 16b compresses 2000 kg of fuel gas per hour and discharges it downstream, the discharge snubber 20b The fuel gas that has flowed out and passed through the heat exchanger 22b is caused to flow back by 500 kg per hour and returned to the suction snubber 18b. Thus, the degree of opening of the control valve 26b is controlled so that the fuel gas from the discharge snubber 20b flows back 500 kg per hour. Thereby, 1500 kg of fuel gas can flow constantly from the heat exchanger 22b to the downstream side per hour. Therefore, the pressure of the fuel gas in the discharge snubber 20b, in other words, the high-pressure gas flow path can be kept constant.

  However, when the pressure of the fuel gas in the suction snubber 18b changes and the discharge amount of the fuel gas changes from 2000 kg per hour, the pressure of the discharge snubber 20b does not exceed the pressure set by the safety valve. The amount of fuel gas that flows backward through the bypass pipe 24b must also be controlled in accordance with the change in the discharge amount of the fuel gas. Further, when the amount of fuel gas supplied from the upstream side to the suction snubber 18b increases, and further, when the required amount of fuel gas to be flowed from the discharge snubber 20b changes, the pressure of the discharge snubber 20b is In order not to exceed the set pressure, the amount of fuel gas flowing back through the bypass pipe 24b must be adjusted. If the amount of fuel gas flowing back to the bypass pipe 24b is not adjusted, the safety valve of the discharge snubber 20b is opened, and large pressure fluctuation at the time of opening may cause control disturbance of pressure in each stage, and pressure control may become unstable. There is.

In consideration of such a point, in the present embodiment, the opening degree of the control valves 26a to 26e provided in the bypass pipes 24a to 24e is controlled according to the pressure of the fuel gas of the discharge snubbers 20a to 20e of the fuel gas. The The control of the opening degree of the control valves 26a to 26e is performed by an opening degree command value set by the control devices 28a to 28e. That is, the opening command value set for each of the control valves 26a to 26e controls the opening of the control valves 26a to 26e.
In the control devices 28a to 28e, command values are set according to the pressure difference between the measurement results measured by the pressure gauges 19a to 19e and the determined target pressure. The target pressure determined by the control device 28e is sent from the governor 15c as described above.

  The check valves 34a to 34e with unloaders are check valves in which unloaders 41a to 41e are provided between the suction snubbers 18a to 18e of the compression mechanisms 13a to 13e and the gas compressors 16a to 16e. In the loaded state described later, the check valves 34a to 34e restrict the flow of fuel gas to the one-way flow of fuel gas from the suction snubbers 18a to 18e to the compression chambers 17a to 17e of the gas compressors 16a to 16e, In the unloaded state due to the action of the unloaders 41a to 41e, the flow of fuel gas in both directions between the suction snubbers 18a to 18e and the compression chambers 17a to 17e is allowed. FIG. 3 is a diagram for explaining the unloader-equipped check valves 34 a to 34 e of the present embodiment. FIGS. 4A and 4B are diagrams for explaining an example of the configurations of the check valves 34a to 34e and the unloaders 41a to 41e. Hereinafter, when the check valves 34a to 34e are described as representatives, they are referred to as check valves 34, and each member constituting the check valve 34 with an unloader is also indicated by only numbers without being attached with the symbols a to e. In this embodiment, the unloader 41 having the configuration shown in FIGS. 4A and 4B is used. The unloader 41 is a mechanism that can switch the function of the reverse valve 34 between the load state and the unload state. There is no particular limitation if it is.

The check valve 34 shown in FIGS. 4A and 4B includes a valve seat 51, a valve receiver 59, and a plurality of valve plates 53, 55, 57 arranged between the valve seat 51 and the valve receiver 59. Have. The valve seat 51 is disposed on the compression chamber 17a side, and the valve receiver 59 is disposed on the suction snubbers 18a to 18e side of the gas supply line. The valve seat 51, the valve plates 53 to 57, and the valve seat 59 are all plate-like members. A shaft 52 extending toward the valve seat 59 is provided at the center of the valve seat 51. A shaft 52 is configured to be disposed through the valve plates 53 to 57 and the valve receiver 59. The check valve 34 further includes a biasing member (not shown) such as a coil spring. In a state where an external force is not acting on the check valve 34 (for example, an unload state described later), the valve seat 51, the valve The plates 53 to 57 and the valve plate 59 are spaced apart from one another. A plurality of recesses 51a serving as fuel gas passages are formed in the region of the valve seat 51 on the outer circumferential side of the shaft 52, and a plurality of valve plates 53 to 57 and valve bearings 59 serve as fuel gas passages. The concave portions 53a, 55a, 57a, 59a are formed. Recesses 53a, 55a, 57a, 59a are integral holes in the extending direction of shaft 52 in a state in which valve plates 53 to 57 and valve receiver 59 are in contact with each other as shown in FIG. 4A. A space is formed, and the space of this integral hole is closed by the valve seat 51. Therefore, in the state where the check valve 22 is closed, it can not flow in the direction shown by the arrow shown in FIG. 4A (direction from the compression chambers 17a to 17e to the suction snubbers 18a to 18e), and reverse flow is caused. I can stop. On the other hand, in the direction from the suction snubbers 18a to 18e to the compression chambers 17a to 17e, the fuel gas overcomes the biasing force of the above-mentioned biasing member (not shown) and the valve seat 51 and the valve plate 53 are separated. Space is open and fuel gas flows.
On the other hand, in the state where the check valve 22 is open, the fuel gas can flow, for example, to the arrow shown in FIG. 4B (from the compression chamber 21a to the suction snubber 23), and also flows in the direction opposite to the arrow. be able to.

  An unloader 41 is provided to such a check valve 34. As shown in FIG. 4B, the unloader 41 includes a casing 61, a diaphragm 63 that can move in the casing 61, a rod 65 connected to the diaphragm 63, and an air pressure (not shown) that supplies air pressure to the casing 61. And a supply device. The diaphragm 63 is biased in the casing 61 by a biasing member (not shown) so as to project the rod 65 (projecting downward in FIGS. 4A and 4B). The tip of the rod 65 (the lower end in FIGS. 4A and 4B) is in contact with a member 67 attached to the valve seat 51 of the check valve 34, and the rod 67 projects to form the members 67, A pressure contact force acts on the check valve 22 via 68. The members 67 and 68 are members for transmitting the pressure contact force from the rod 65 to a wider area of the valve seat 51. With such a configuration, the rod 65 moves forward and the valve seat 51 and the valve seat 59 are closed by the pressure contact force of the rod 65, so that the function of the check valve 34 can be brought into a normal state (load state). On the other hand, when the rod 65 is retracted, the valve seat 51 and the valve receiver 59 are opened, so that the function of the check valve 34 cannot be exhibited (unloaded state). Switching between the loaded state and unloaded state of the check valve 34 by the unloader 41 is performed under the control of the control devices 28a to 28e. At this time, the control devices 28a to 28e control the operation of the unloader 41, and the control devices 28a to 28e output a control signal for switching from the load state to the unload state before stopping the operation of the gas compressors 16a to 16e. Preferably sent to

In such a fuel gas supply system 10, the amount of fuel gas used may be zero for stopping the propulsion engine 14 or switching the fuel used for the propulsion engine 14 to another fuel. . In this case, since it is also difficult to switch the driving of the gas compressors 16a to 16e instantaneously in response to the switching of use of the fuel gas, the pressure of the fuel gas may be high on the downstream side. For example, when the supply of fuel gas to the propulsion engine 14 is stopped, the operation for stopping the driving of the gas compressors 16a to 16e is started later, and the control valves 26a to 26e are also started later for the opening change operation. To do. Therefore, during these delay times, the pressure of the fuel gas in the suction snubber of the downstream compression mechanism tends to be higher than the pressure of the fuel gas in the discharge snubber of the upstream adjacent compression mechanism. In order to prevent the backflow of the fuel gas caused by the height of the fuel gas, check valves 32a to 32e are provided in the gas supply line connecting the compression mechanisms 13a to 13e. The check valves 32a to 32e are
It is provided in the gas supply line between the branch positions of the bypass pipes 24a to 24e and the suction snappers 18b to 18e on the downstream side.

FIG. 5 is a view for explaining the flow of the stop of the supply of the fuel gas, which is an example of the fuel gas supply method of the present embodiment.
First, when the fuel gas supply system 10 stops supplying the fuel gas to the propulsion engine 14, the fuel gas supply system 10 closes the fuel gas supply valve to the propulsion engine 14 and sets the check valve 34 to the unloader. As shown in FIG. 4B, the unloaded state is set by the action of 41 (step S10). Specifically, from the loading state where the flow of fuel gas is limited to the one-way flow from suction snubbers 18a-18e to compression chambers 17a-17e, the flow of fuel gas is drawn from suction snubbers 18a-18e and compression chambers 17a. Switch to an unload state allowing flow in both directions between ~ 17e. The switching from the loading state to the unloading state can be performed in a short time. Thereby, even if the gas compressors 16a to 16e are driven, the fuel gas is not supplied from the gas compressors 16a to 16e to the discharge snubbers 20a to 20e. For this reason, the pressure of the fuel gas in the discharge snubbers 20a to 20e is unlikely to increase.

  Further, in the check valves 32a to 32d, in the unloading state, part of the fuel gas flowing from the discharge snubbers 20a to 20e through the heat exchangers 22a to 22e is suctioned via the bypass pipes 24a to 24e. To 18e to prevent the backflow of fuel gas caused by the pressure of the discharge snubbers 20a to 20e being reduced. The backflow of the fuel gas is directed from the suction snubbers 18b to 18e of the compression mechanisms 13b to 13e located on the downstream side in the fuel gas supply direction toward the discharge snubbers 20a to 20e located on the upstream side (a reverse of the fuel gas supply direction This is the flow of fuel gas that flows in the direction.

While preventing the backflow, the fuel gas supply system 10 closes the control valves 26a to 26e to make the flow rate of the fuel gas in the bypass pipes 24a to 24e 0 (step S12).
After the flow rate of the fuel gas is reduced to 0, the operation of the gas compressors 16a to 16e is stopped (step S14).
In this way, the check valves 32a to 32d can prevent the fuel gas from flowing back between the multistage compression mechanisms 13a to 13e.
The discharge snubbers 20a to 20e are closed by the check valves 32a to 32e, the control valves 26a to 26e, and the stopped gas compressors 16a to 16e, so the same compression mechanism 13a to 13b as the discharge snubbers 20a to 20e are used. The suction snubbers 18a to 18e associated with 13e are held in a state where there is a pressure difference of the fuel gas. That is, while the operation of the gas compressors 16a-16e is stopped, the pressure of the discharge snubbers 20a-20e of the compression mechanisms 13a-13e of the fuel gas supply system 10 is maintained higher than the pressure of the suction snubbers 18a-18e. ing. For this reason, when the gas compressors 16a to 16e are restarted, stable supply of the fuel gas to the propulsion engine 14 can be realized in a short time.

FIG. 6 is a diagram for explaining a flow of restarting the gas compressors 16a to 16e, which is another example of the fuel gas supply method of the present embodiment.
First, the fuel gas supply system 10 starts driving the gas compressors 16a to 16e (step S20). Specifically, before the gas compressors 16a to 16e are driven, the check valves 34a to 34e are in an unloaded state, and the control valves 26a to 26e are closed. In this state, each of the compression mechanisms 13a to 13e starts the operation of the gas compressors 16a to 16e.

Next, when the operations of the gas compressors 16a to 16e are in a steady state, the control valves 26a to 26e are opened (step S22). Further, the control valves 26a to 26e are opened, and the state of the check valves 34a to 34e is switched from the unloaded state to the loaded state by the action of the unloader 41, thereby releasing the unloaded state (step S24).
While the operation of the gas compressors 16a to 16e is stopped before the gas compressors 16a to 16e are restarted, the pressure of the discharge snubbers 20a to 20e of the compression mechanisms 13a to 13e of the fuel gas supply system 10 is the pressure of the suction snubbers 18a to 18e. It is preferable to maintain a high state as compared with. Thereby, when the gas compressors 16a to 16e are restarted, a stable supply of the fuel gas to the propulsion engine 14 can be realized in a short time.

  The fuel gas supply system and the fuel gas supply method of the present invention have been described in detail above. However, the present invention is not limited to the above-described embodiment, and various improvements and modifications can be made without departing from the gist of the present invention. Of course it is also good.

DESCRIPTION OF SYMBOLS 10 Fuel gas supply system 12 LNG tank 13a-13e Compression mechanism 14 Propulsion engine 15a Main shaft 15b Propeller 15c Governor 15d Tachometer 16a-16e Gas compressor 17a-17e Compression chamber 18a-18e Suction snubber 19a-19e Pressure gauge 20a-20e 22a to 22e heat exchanger 24a to 24e bypass pipe 26a to 26e control valve 28a to 28e control device 32a to 32e, 34a to 34e check valve 41, 41a to 41e unloader 51 valve seat 52 shaft 53, 55, 57 valve plate 53a , 55a, 57a, 59a Recess 59 Valve holder 61 Casing 63 Diaphragm 65 Rod 67, 68 Member

Claims (5)

A fuel gas supply system for supplying fuel gas to a propulsion engine of a ship, comprising:
A fuel gas source;
A plurality of compression mechanisms provided in series in a gas supply line for supplying a fuel gas supplied from the fuel gas source to a propulsion engine of a ship, and compressing the fuel gas and flowing it to the side of the propulsion engine; ,
Each of the compression mechanisms is provided upstream of the gas compressor in the supply direction of the fuel gas to the propulsion engine so as to be associated with the gas compressor for compressing the fuel gas and the gas compressor, and the gas A low pressure gas flow path for supplying the fuel gas toward a compression chamber of a compressor, and the fuel gas provided downstream of the gas compressor in the supply direction, and promoting the fuel gas compressed in the compression chamber of the gas compressor A high pressure gas flow path supplied toward an engine, a bypass pipe connecting the low pressure gas flow path and the high pressure gas flow path without passing through the compression chamber, and a flow rate of the fuel gas in the bypass pipe are controlled a control valve for the flow of said fuel gas, allowing both directions of flow between the compression chamber and the low-pressure gas passage An unloader capable of switching between an unloading state and a loading state in which the flow of the fuel gas is restricted from the low pressure gas passage to the flow in one direction from the low pressure gas passage, and a control unit for controlling the operation of the unloader And
A check valve for preventing the fuel gas from flowing backward in the reverse direction of the supply direction is provided in each of the gas supply lines connecting the plurality of compression mechanisms ,
The said control part sends the control signal which switches from the said load state to the said unload state to the said unloader before the operation | movement of the said gas compressor stops, The fuel gas supply system characterized by the above-mentioned . A fuel gas supply method using a fuel gas supply system for supplying a fuel gas to a propulsion engine of a ship, comprising:
The fuel gas supply system
A fuel gas source,
A plurality of compression mechanisms provided in series with a gas supply line for supplying fuel gas supplied from the fuel gas source to a propulsion engine of a ship, and compressing the fuel gas and flowing it to the side of the propulsion engine; ,
Each of the compression mechanisms is provided on the upstream side of the gas compressor in the supply direction of the fuel gas to the propulsion engine so as to be associated with the gas compressor for compressing the fuel gas and the gas compressor, A low pressure gas flow path for supplying the fuel gas toward the compression chamber of the gas compressor, and the fuel gas provided downstream of the gas compressor in the supply direction and compressed in the compression chamber of the gas compressor A high pressure gas flow path for supply to a propulsion engine, a bypass pipe connecting the low pressure gas flow path and the high pressure gas flow path without passing through the compression chamber, and a flow rate of the fuel gas in the bypass pipe And a control valve to control
When stopping the operation of the gas compressor,
Each of the compression mechanisms is configured to restrict the flow of the fuel gas from the loaded state in which the flow of the fuel gas is restricted to the flow in one direction from the low pressure gas passage to the compression chamber; Switching to an unloaded condition allowing bi-directional flow to and from the compression chamber;
Due to the unloading state, the fuel gas in the high-pressure gas passage flows into the low-pressure gas passage through the bypass pipe, and the pressure in the high-pressure gas passage is reduced. Preventing a back flow of the fuel gas from one low pressure gas flow path of the compression mechanism located in a direction opposite to the supply direction;
Closing the control valve to prevent the flow rate of the fuel gas in the bypass pipe while preventing the reverse flow; and
And a step of stopping the operation of the gas compressor after setting the flow rate of the fuel gas to zero. When starting the operation of the gas compressor from the stop of the operation of the gas compressor,
Starting the operation of the gas compressor with the control valve closed and the unload condition;
3. The fuel gas supply method according to claim 2 , further comprising the step of opening the control valve and switching from the unloading state to the loading state when the operation of the gas compressor becomes a steady state. A fuel gas supply method using a fuel gas supply system for supplying a fuel gas to a propulsion engine of a ship, comprising:
The fuel gas supply system
A fuel gas source,
A plurality of compression mechanisms provided in series with a gas supply line for supplying fuel gas supplied from the fuel gas source to a propulsion engine of a ship, and compressing the fuel gas and flowing it to the side of the propulsion engine; .
Each of the compression mechanisms is provided on the upstream side of the gas compressor in the supply direction of the fuel gas to the propulsion engine so as to be associated with the gas compressor for compressing the fuel gas and the gas compressor, A low pressure gas flow path for supplying the fuel gas toward the compression chamber of the gas compressor, and the fuel gas provided downstream of the gas compressor in the supply direction and compressed in the compression chamber of the gas compressor A high pressure gas flow path for supply to a propulsion engine, a bypass pipe connecting the low pressure gas flow path and the high pressure gas flow path without passing through the compression chamber, and a flow rate of the fuel gas in the bypass pipe And a control valve to control
Each of the compression mechanisms is in an unloaded state allowing flow of the fuel gas in both directions between the low pressure gas flow path and the compression chamber during cessation of operation of the gas compressor, and The control valve is in a closed state, and starting the operation of the gas compressor in the unloaded state and the closed state;
And (d) opening the control valve and switching from the unloading state to the loading state when the operation of the gas compressor is in a steady state. Wherein during the stop of the operation of the gas compressor, the compression mechanism pressure of each of the high-pressure gas passage of the fuel gas supply system is to maintain a high state compared to the pressure of the low-pressure gas passage, according to claim 2 The fuel gas supply method of any one of -4 .

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