JP6959804B2 - Vessel and LPG temperature / pressure control method - Google Patents

Description

The present invention relates to a ship including a propulsion engine fueled by LPG.

In conventional ships, the fuel for the propulsion engine is generally fuel oil such as heavy oil or light oil, or LNG (Liquefied Natural Gas). In recent years, it has also been proposed to use LPG (Liquefied Petroleum Gas) as a fuel for a propulsion engine. For example, Patent Document 1 discloses a ship that supplies LPG as a liquid from a fuel tank to a propulsion engine.

Korean Publication No. 2012-0113398 Gazette

When using LPG as fuel, connect the fuel tank and the propulsion engine by a fuel supply line and a fuel recovery line, and use the required amount in the engine while circulating the LPG between the fuel tank and the engine. Can be considered.

By the way, when LPG is circulated between the fuel tank and the engine as described above, it is desirable to supply the engine with fuel slightly larger than the fuel consumption of the engine. To achieve this, it is conceivable to adjust the rotation speed of the pump provided in the fuel supply line according to the fuel consumption of the engine. Further, in order to properly inject fuel in the engine, it is necessary to secure the fuel supply pressure to the engine above a certain value. Therefore, it is desirable to set the minimum rotation speed for the pump.

For example, in order to keep LPG, which is mainly composed of propane gas, in a liquid state at atmospheric pressure, it is necessary to keep the fuel tank at −42 ° C. or lower. Therefore, it is conceivable to use the fuel tank as a pressure vessel and change the temperature of LPG in the fuel tank according to the atmospheric temperature. That is, the high pressure in the fuel tank keeps the LPG in equilibrium. However, in this case, the pressure of the air layer in the fuel tank (saturated vapor pressure in the case of only PG in which the components of the air layer are vaporized) changes greatly depending on the temperature of the LPG in the fuel tank. When the temperature of the LPG in the fuel tank is low, the pressure range to be boosted by the pump is large, and when the temperature of the LPG in the fuel tank is high, the pressure range to be boosted by the pump is small.

Then, when the temperature of the LPG in the fuel tank is low (when the pressure in the air layer is low and the pressure range to be boosted by the pump is large), when the LPG is used as fuel, the supply pressure of the LPG is adjusted by the engine. It may not be possible to boost the pressure to the required pressure and the engine may not run smoothly.

Therefore, an object of the present invention is to provide a ship capable of smoothly operating a propulsion engine at the start of using LPG.

The ship according to one embodiment of the present invention includes a fuel tank for storing LPG so that the temperature of LPG changes according to the atmospheric temperature, a propulsion engine using LPG as fuel, and LPG from the fuel tank to the engine. The fuel supply line for supplying fuel, the pump provided in the fuel supply line, the fuel recovery line for recovering unused LPG from the engine to the fuel tank, and the pressure of the air layer in the fuel tank are detected. A pressure gauge and a control device for controlling the rotation speed of the pump are provided, and the control device is used when the pressure detected by the pressure gauge is equal to or lower than a predetermined value during a period when LPG is not used as fuel. , The pump is operated to circulate the LPG in the fuel tank to the fuel tank via the engine.

The ship according to another embodiment of the present invention includes a fuel tank for storing LPG so that the temperature of LPG changes according to the atmospheric temperature, a propulsion engine using LPG as fuel, and LPG from the fuel tank to the engine. A fuel supply line for supplying fuel, a pump provided in the fuel supply line, a fuel recovery line for recovering unused LPG from the engine to the fuel tank, and a branch from the fuel supply line on the downstream side of the pump. The control device includes a fuel recovery line or a bypass line connected to the fuel tank, a pressure gauge for detecting the pressure of the air layer in the fuel tank, and a control device for controlling the rotation speed of the pump. When the pressure detected by the pressure gauge is equal to or less than a predetermined value during the period when the LPG is not used as fuel, the pump is operated to transfer the LPG in the fuel tank to the engine and / or the bypass line. It is circulated to the fuel tank through the fuel tank.

The LPG temperature / pressure control method according to one embodiment of the present invention includes a fuel tank that stores the LPG so that the temperature of the LPG changes according to the atmospheric temperature, a propulsion engine that uses the LPG as fuel, and the fuel tank. It is applied to a ship including a fuel supply line for supplying LPG from the engine to the engine, a pump provided in the fuel supply line, and a fuel recovery line for recovering unused LPG from the engine to the fuel tank. An LPG temperature / pressure control method in which the pressure of the air layer in the fuel tank falls below a predetermined value while the LPG is not used as fuel, and the temperature of the LPG in the fuel tank falls below a predetermined value. And / or when the condition that the pump operation command member was operated by the crew is satisfied, the pump is operated and the LPG in the fuel tank is transferred to the fuel tank via the engine. Circulate.

According to the above configuration, if the pressure in the air layer is low during the period when LPG is not used as fuel, the pump operates and LPG circulates. The temperature of LPG rises due to the heat input from the pump as it passes through the pump. It should be noted that the heat input from the engine may increase even when the engine passes through. By returning the LPG whose temperature has been raised in the circulation process to the fuel tank in this way, the temperature of the LPG in the fuel tank can be raised, and the pressure in the air layer can also be raised. Therefore, at the start of use of LPG, the supply pressure of LPG can be boosted to the pressure required by the engine by the pump, and the engine can be operated smoothly.

According to the present invention, it is possible to provide a ship capable of smoothly operating a propulsion engine at the start of using LPG.

It is a schematic block diagram of the ship which concerns on 1st Embodiment. It is a schematic block diagram of the ship which concerns on a modification. It is a schematic block diagram of the ship which concerns on 2nd Embodiment.

Hereinafter, embodiments will be described with reference to the drawings. The same or corresponding elements are designated by the same reference numerals throughout the drawings, and duplicate detailed description will be omitted.

(First Embodiment)
FIG. 1 shows a ship according to the first embodiment. The ship 1 includes a fuel tank 2 for storing LPG so that the temperature of LPG changes according to the atmospheric temperature, and a propulsion engine 11 using LPG as fuel. The main component of LPG may be propane (propane gas) or butane (butane gas).

In the present embodiment, the fuel tank 2 is composed of a storage tank 21 having a relatively large volume and a service tank 22 having a relatively small volume. Both the storage tank 21 and the service tank 22 are pressure vessels having a pressure resistance higher than that of atmospheric pressure. The storage tank 21 and the service tank 22 are connected to each other by a relay line 26.

LPG is introduced into the storage tank 21 from the LPG supply source through the fuel introduction line 23. The LPG supply source may be a cargo tank mounted on the ship 1, an LPG supply facility on land, or an LPG fuel supply ship.

A pump 25 is installed inside the storage tank 21. The number of pumps 25 may be one or plural. The upstream end of the relay line 26 is connected to the pump 25. The downstream end of the relay line 26 is open in the service tank 22. LPG is supplied from the storage tank 21 to the service tank 22 through the relay line 26 by the pump 25. However, the pump 25 may be provided outside the storage tank 21 and in the middle of the relay line 26.

In the present embodiment, the storage tank 21 is not provided with means for maintaining the LPG at a low temperature (for example, a heat insulating material), and the temperature of the LPG in the storage tank 21 changes according to the atmospheric temperature. On the other hand, the LPG introduced from the LPG supply source is often about −42 ° C. when the LPG is propane gas. Therefore, the fuel introduction line 23 is provided with a heater 24 that heats LPG to, for example, −5 ° C. or higher. However, if the land-based LPG supply facility or LPG fuel supply ship, which is the LPG supply source, is equipped with a heater and the temperature of the LPG delivered to the ship 1 is -5 ° C or higher, the heater 24 is unnecessary. be.

When the component of the air layer in the storage tank 21 is only vaporized PG, the pressure of the air layer in the storage tank 21 is the saturated vapor pressure of LPG. For example, when the temperature in the storage tank 21 is 25 ° C., the pressure of the air layer (saturated vapor pressure) in the storage tank 21 is about 0.9 MPa in gauge pressure. Hereinafter, all pressure indications are gauge pressures. Since the saturated vapor pressure of LPG is about 1.7 MPa at 50 ° C., the storage tank 21 is configured to withstand up to 1.8 MPa, for example. For reference, the saturated vapor pressure of LPG is about 0.4 MPa at 0 ° C.

Like the storage tank 21, the service tank 22 is not provided with a means for keeping the LPG at a low temperature, and the temperature of the LPG in the service tank 22 changes according to the atmospheric temperature. When the component of the air layer in the service tank 22 is only vaporized PG, the pressure of the air layer in the service tank 22 is the saturated vapor pressure of LPG.

When the LPG is circulated between the engine 11 and the service tank 22 as described later, the temperature of the LPG in the service tank 22 may be higher than the atmospheric temperature. For example, when the temperature of the LPG in the service tank 22 is 60 ° C., the pressure (saturated vapor pressure) of the air layer in the service tank 22 is about 2.1 MPa. The service tank 22 is configured to withstand up to 2.2 MPa, for example.

The service tank 22 is connected to the propulsion engine 11 by a fuel supply line 31 and a fuel recovery line 41. LPG is supplied from the service tank 22 to the engine 11 through the fuel supply line 31, and unused LPG is recovered from the engine 11 to the service tank 22 through the fuel recovery line 41. In other words, LPG circulates between the service tank 22 and the engine 11 through the fuel supply line 31 and the fuel recovery line 41.

The upstream end of the fuel supply line 31 is connected to the lower part of the service tank 22. The downstream end of the fuel recovery line 41 is open in the service tank 22.

The engine 11 is, for example, a diesel cycle or Otto cycle reciprocating engine. Although not shown, the engine 11 includes a main flow path connecting the downstream end of the fuel supply line 31 and the upstream end of the fuel recovery line 41, and a plurality of fuel injection valves connected in parallel to each other in the main flow path. ..

The fuel supply line 31 is provided with a pump 32, a heater 33, and a shutoff valve 34 in this order from the upstream side. The heater 33 heats the LPG to the required temperature of the engine 11 (for example, 45 ° C.).

The relay line 26 is provided with a heater 27 for heating the LPG supplied from the storage tank 21 to the service tank 22. While the engine 11 is in operation, an amount of LPG corresponding to the fuel consumption Qe of the engine 11 is supplied from the storage tank 21 to the service tank 22. The heater 27 is used when it is difficult to heat the LPG to the required temperature of the engine 11 only by the heater 33. The heater 27 may be omitted.

The fuel recovery line 41 is provided with a first pressure regulating valve 42, a shutoff valve 43, a cooler 44, and a second pressure regulating valve 45 in this order from the upstream side. The cooler 44 cools the LPG to a predetermined temperature (eg, 40 ° C.). The cooler 44 may be omitted.

In the present embodiment, the fuel supply line 31 and the fuel recovery line 41 are connected by the first bypass line 51. The first bypass line 51 branches from the fuel supply line 31 between the heater 33 and the shutoff valve 34, and is connected to the fuel recovery line 41 between the shutoff valve 43 and the cooler 44. The first bypass line 51 is provided with a flow rate control valve 52.

Further, in the present embodiment, the second bypass line 53 is also adopted. The second bypass line 53 branches from the fuel supply line 31 between the pump 32 and the heater 33 and is connected to the service tank 22. The second bypass line 53 is provided with a flow rate control valve 54. However, either one of the first bypass line 51 and the second bypass line 53 may be omitted.

The pump 32, the shutoff valves 34, 43, the pressure regulating valves 42, 45, and the flow rate control valves 52, 53 described above are controlled by the control device 6. However, in FIG. 1, only a part of the signal lines are drawn for the sake of simplification of the drawing. The control device 6 is, for example, a computer having a memory such as a ROM or RAM and a CPU, and a program stored in the ROM is executed by the CPU. The control device 6 may be a single device or may be divided into a plurality of devices (for example, an engine control device and a fuel supply control device).

The control device 6 is electrically connected to the first to third pressure gauges 71 to 73 and the flow meter 81. The first pressure gauge 71 and the flow meter 81 are used to control the pump 32 and the flow control valves 52 and 54, the second pressure gauge 72 is used to control the first pressure control valve 42, and the third pressure gauge 73 is the first. 2 Used to control the pressure control valve 45.

Here, the engine 11 may be an engine that uses only LPG as fuel, or may be a dual fuel engine that uses LPG and fuel oil such as heavy oil or light oil as fuel.

In the case of an engine using only LPG as fuel, the timing of starting to use LPG as fuel corresponds to the timing of starting the operation of the engine 11. The period during which the use of LPG is stopped corresponds to the period during which the engine 11 is stopped.

In the case of a dual fuel engine, the timing of starting the use of LPG as fuel includes the timing of starting the operation of the engine 11 and switching the fuel used by the engine 11 to the LPG while the engine 11 is in operation or the engine 11 Includes the timing of adding LPG to the fuel used in. The period during which the use of LPG is stopped includes a period during which the engine 11 is stopped and a period during which the engine 11 is operating using only fuel oil as fuel.

Regarding the shutoff valves 34 and 43, the control device 6 closes the shutoff valves 34 and 43 during the period when the supply of LPG to the engine 11 is stopped. During the period of supplying LPG to the engine 11, the control device 6 opens the shutoff valves 34 and 43. While the engine 11 is stopped, the flow path between the shutoff valves 34 and 43 (the downstream part of the fuel supply line 31, the main flow path of the engine 11 and the upstream part of the fuel recovery line 41) is purged with the inert gas.

When LPG is used as fuel in the engine 11, pressure control, flow rate control and temperature control of LPG are executed as follows.

The first pressure gauge 71 is provided in the service tank 22 and detects the pressure of the air layer in the service tank 22. The flow meter 81 is provided in the fuel supply line 31 on the downstream side of the branch point with the first bypass line 51, and detects the supply flow rate Qi of LPG flowing into the engine 11 through the fuel supply line 31. The control device 6 keeps the flow control valve 52 fully closed unless the rotation speed of the pump 32 reaches the minimum rotation speed. Then, the control device 6 controls the pump 32 so that the supply flow rate Qi detected by the flow meter 81 becomes a predetermined value V corresponding to the fuel consumption Qe of the engine 11. In the present embodiment, the predetermined value V is the value obtained by multiplying the fuel consumption Qe of the engine 11 by the coefficient C (V = Qe × C). For example, the coefficient C is usually 1.1 to 1.50. The coefficient C may be a fixed value set within this numerical range, or may be variably set within this numerical range.

For example, the control device 6 may determine the fuel consumption Qe of the engine 11 based on the operation amount of the telegraph lever operated by the operator. Alternatively, when the control device 6 is divided into an engine control device that controls the engine 11 and a fuel supply control device that controls the pump 32 and various valves, the fuel supply control device is calculated by the engine control device. The fuel consumption Qe of the engine 11 may be determined based on the value related to the fuel consumption.

When the rotation speed of the pump 32 reaches the minimum rotation speed as a result of the control based on the supply flow rate Qi detected by the flow meter 81, the control device 6 sets the supply flow rate Qi detected by the flow meter 81 to the predetermined value V described above. Either one of the flow rate control valves 52 and 54 is controlled so as to be. Specifically, the control device 6 increases the opening degree of either one of the flow control valves 52 and 54 as the fuel consumption Qe of the engine 11 decreases.

The second pressure gauge 72 is provided in the fuel supply line 31 on the downstream side of the heater 33, and detects the pressure of the LPG supplied to the engine 11. In the present embodiment, the second pressure gauge 72 is located on the downstream side of the shutoff valve 34, but it may be located on the upstream side of the shutoff valve 34. The control device 6 controls the first pressure regulating valve 42 so that the pressure detected by the second pressure gauge 72 becomes the required pressure of the engine 11 (for example, 5.0 to 6.0 MPa).

The third pressure gauge 73 is provided in the fuel recovery line 41 between the first pressure regulating valve 42 and the second pressure regulating valve 45, and detects the pressure of LPG after the pressure is reduced by the first pressure regulating valve 42. do. In the present embodiment, the third pressure gauge 73 is located on the upstream side of the cooler 44, but may be located on the downstream side of the cooler 44.

The temperature of the LPG rises slightly as the LPG passes through the engine 11 (eg, 55 ° C.). Therefore, in order to prevent the LPG decompressed by the first pressure regulating valve 42 from vaporizing, the control device 6 sets the pressure detected by the third pressure gauge 73 to be higher than the saturated steam pressure at the assumed maximum temperature. The second pressure regulating valve 45 is controlled so as to have a high set value (for example, 2.0 MPa).

Even when the use of LPG is stopped, the temperature control of LPG and thus the pressure control is executed. In particular, temperature control of LPG in the fuel tank 2 and control of the pressure of the air layer in the fuel tank 2 are executed.

Specifically, the control device 6 is set when the pressure of the air layer in the service tank 22 detected by the first pressure gauge 71 is equal to or less than a predetermined value during the period when the LPG is not used as fuel, or when the LPG is not used as fuel. When the pump command member 61 is operated by a member, the pump 32 is operated. At this time, one of the shutoff valves 34 and 43 and / or the flow control valves 52 and 54 is opened. When the shutoff valves 34 and 42 are opened, the LPG in the service tank 22 circulates to the service tank 22 via the fuel supply line 31 and the engine 11 (particularly, its main flow path). When the flow control valve 52 is opened, the LPG in the service tank 22 circulates to the service tank 22 via the fuel supply line 31 and the first bypass line 51. When the flow control valve 54 is opened, the LPG in the service tank 22 circulates to the service tank 22 via the fuel supply line 31 and the second bypass line 53. When either the shutoff valves 34, 43 and the flow control valves 52, 54 are open, the LPG in the service tank 22 is the engine 11, the fuel recovery line 41, and / or the first bypass line 51 or It circulates to the service tank 22 via the second bypass line 53.

As described above, the pressure of the gas layer of the service tank 22 (saturated vapor pressure of LPG) when the temperature of the LPG in the service tank 22 is 0 ° C. is about 0.4 MPa, whereas the LPG is used as fuel. The required pressure of the engine 11 in use is 5.0 to 6.0 MPa. If the pressure of the air layer in the service tank 22 is lower than a predetermined value, even if the engine 11 is to be operated using LPG as fuel, the pump 31 cannot boost the supply pressure of LPG to the required pressure, so the engine 11 is operated by LPG. I can't drive. Until the required pressure can be reached (until the pressure in the air layer exceeds a predetermined value), the engine 11 cannot be operated using LPG. Therefore, the start of operation of the engine 11 using LPG is the start. It will be delayed by a minute.

As described above, when the control device 6 circulates the LPG through the engine 11 and / or the first bypass line 51 or the second bypass line 53 while the LPG is not used as fuel, the temperature of the LPG is increased. Increases at least with the heat input from the pump 32. In the case of a dual fuel engine, if the engine 11 is operating using fuel oil, the LPG passes through the engine 11 and circulates, so that heat is also input from the engine 11 and the temperature of the LPG is likely to rise. Further, in the present embodiment, since the heater 33 is arranged between the pump 32 and the branch point of the first bypass line 51 on the fuel supply line 31, LPG circulation via the first bypass line 51 Even at times, the temperature of the LPG can be raised by the heater 33. Since the cooler 44 is a temperature controller that regulates the temperature of LPG at a temperature lower than that of the heater 33, the temperature of the LPG is lower than the regulated temperature in the cooler 44 when the LPG is circulated due to its low pressure. Therefore, the "cooler 44" can function as a heater.

Due to the circulation of LPG, the temperature of LPG in the service tank 22 rises, and accordingly, the pressure of the air layer in the service tank 22 (saturated vapor pressure of LPG) also rises. When the pressure in the air layer exceeds a predetermined value, the pump 32 is stopped to stop the circulation of LPG. In order to prevent the pump 32 from being frequently operated and stopped, the threshold value for determining the circulation stop may be set to a value larger than the threshold value for determining the start of circulation (high pressure value).

The rotation speed of the pump 32 is not particularly limited, but may be constant at the minimum rotation speed, or may be variable depending on the pressure of the detected air layer. By increasing the rotation speed of the pump 32 when the pressure in the air layer is low, the temperature can be raised at an early stage.

Since the pressure of the air layer in the service tank 22 is maintained above a predetermined value when the use of LPG is stopped in this way, the supply pressure of LPG is supplied by the pump 32 when the use of LPG is started as fuel. Can be boosted to the pressure required by the engine 11, and the operation of the engine using LPG can be started smoothly and quickly.

(Second Embodiment)
FIG. 2 is a schematic configuration diagram of the ship 101 according to the second embodiment. As shown in FIG. 2, the bypass lines 51, 53 and the flow control valves 52, 54 may be omitted. In this case, the control device 6 operates the pump 32 when the pressure of the air layer in the service tank 22 detected by the first pressure gauge 71 is equal to or less than a predetermined value when the use of LPG is stopped. , The LPG in the service tank 22 is circulated to the service tank 22 via the engine 11. Also in the present embodiment, similarly to the first embodiment, when the use of LPG as fuel is started, the supply pressure of LPG can be increased to the pressure required by the engine 11 by the pump 32, and the engine using LPG can be used. The operation can be started smoothly and quickly.

(Modification example)
FIG. 3 is a schematic configuration diagram of the ship 201 according to the modified example. As shown in FIG. 3, the flow meter 81 may be provided on the fuel recovery line 41 on the upstream side of the shutoff valve 42 to detect the outflow rate Qo of the LPG from the engine 11. That is, the control device 6 may control the pump 32 and the flow rate control valve 52 so that the outflow flow rate Qo detected by the flow meter 81 becomes a predetermined value V'corresponding to the fuel consumption Qe of the engine 11. .. In this case, the predetermined value V'is, for example, a value obtained by multiplying the fuel consumption Qe of the engine 11 by a coefficient C of usually 0.1 to 0.50. In this case as well, the coefficient C may be a fixed value set within the numerical range, or may be variably set within the numerical range.

Further, the predetermined values V and V'do not necessarily have to be constant, and the control device 6 may increase the predetermined values V and V'when the rotation speed of the pump 32 reaches the minimum rotation speed. For example, in the configuration shown in FIG. 1, the predetermined value V may be increased to a flow rate within the range of 1.1 × Qe to 11.0 × Qe. Alternatively, in the configuration shown in FIG. 3, the predetermined value V'may be increased to a flow rate within the range of 0.1 × Qe to 10.0 × Qe.

When the predetermined values V and V'are constant when the rotation speed of the pump 32 reaches the minimum rotation speed and the flow control valve 54 provided in the second bypass line 53 is opened, the pump 32 The surplus, which is obtained by subtracting the predetermined values V and V'from the discharge flow rate Q, is returned to the service tank 22 through the second bypass line 53. Since the excess portion receives heat from the pump 32, the temperature of the LPG in the service tank 22 rises. On the other hand, if the predetermined values V and V'are increased when the rotation speed of the pump 32 reaches the minimum rotation speed, the LPG returned to the service tank 22 through the second bypass line 53 can be reduced. .. On the other hand, as the predetermined values V and V'increase, the LPG passing through the engine 11 also increases, and the increased amount is cooled by the cooler 44 provided in the fuel recovery line 41. Therefore, it is possible to suppress an increase in the temperature of the LPG in the service tank 22.

In the above embodiment, the fuel tank 2 is composed of the storage tank 21 and the service tank 22, but the storage tank 21 may be omitted and the fuel tank 2 may be composed of only the service tank 22. That is, LPG may be introduced directly into the service tank 22 from the LPG supply source. However, with the configuration as in the above embodiment, the fuel tank 2 can be divided into a storage tank 21 for introducing LPG and a service tank 22 for circulating LPG.

Since the pressure of the air layer in the service tank 22 (saturated vapor pressure) depends on the temperature in the service tank 22, the temperature in the service tank 22 (the temperature of the air layer is also the liquid layer) instead of the first thermometer 71. A thermometer may be provided to detect the temperature of the pump 32, and whether or not the pump 32 needs to be operated may be determined according to the temperature detected by the thermometer.

1,101,201 Ship 11 Propulsion engine 2 Fuel tank 6 Control device 31 Fuel supply line 32 Pump 41 Fuel recovery line 51,251 Bypass line 61 Pump operation command member 71 First pressure gauge

Claims (3)

A fuel tank that stores LPG so that the temperature of LPG changes according to the atmospheric temperature,
A propulsion engine that uses LPG as fuel,
A fuel supply line that supplies LPG from the fuel tank to the engine,
The pump provided in the fuel supply line and
A fuel recovery line that recovers unused LPG from the engine to the fuel tank,
A pressure gauge that detects the pressure of the air layer in the fuel tank, and
A control device for controlling the rotation speed of the pump is provided.
When the pressure detected by the pressure gauge is equal to or less than a predetermined value during the period when the LPG is not used as fuel, the control device operates the pump and transmits the LPG in the fuel tank via the engine. A ship that circulates to the fuel tank. A fuel tank that stores LPG so that the temperature of LPG changes according to the atmospheric temperature,
A propulsion engine that uses LPG as fuel,
A fuel supply line that supplies LPG from the fuel tank to the engine,
The pump provided in the fuel supply line and
A fuel recovery line that recovers unused LPG from the engine to the fuel tank,
A bypass line that branches off from the fuel supply line on the downstream side of the pump and connects to the fuel recovery line or the fuel tank.
A pressure gauge that detects the pressure of the air layer in the fuel tank, and
A control device for controlling the rotation speed of the pump is provided.
When the pressure detected by the pressure gauge is equal to or less than a predetermined value during the period when the LPG is not used as fuel, the control device operates the pump and uses the LPG in the fuel tank as the engine and / or A ship that circulates to the fuel tank via the bypass line. A fuel tank that stores LPG so that the temperature of LPG changes according to the atmospheric temperature,
A propulsion engine that uses LPG as fuel,
A fuel supply line that supplies LPG from the fuel tank to the engine,
The pump provided in the fuel supply line and
An LPG temperature / pressure control method applied on a ship comprising a fuel recovery line for recovering unused LPG from the engine to the fuel tank.
The condition that the pressure of the air layer in the fuel tank falls below the predetermined value, the condition that the temperature of the LPG in the fuel tank falls below the predetermined value, and / or the crew during the period when the LPG is not used as fuel. An LPG temperature / pressure control method in which the pump is operated and the LPG in the fuel tank is circulated to the fuel tank via the engine when the condition that the pump operation command member is operated is satisfied.

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