JP3533512B2 - Liquefied gas supply system - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquefied gas supply system using an expander (expansion turbine) pump suitable for storage equipment, supply equipment, consumption equipment and the like of liquefied gas such as liquefied natural gas. The present invention relates to a method for starting an expander pump.

[0002]

2. Description of the Related Art FIG. 5 shows a conventional liquefied natural gas (LNG).
The outline of the liquefied gas supply system from the storage to the gas delivery is shown. Liquefied gas is sent from the LNG tanker and stored in the semi-underground tank 1. Then, the liquefied gas stored in the semi-underground tank 1 is pumped up by the first stage (primary) pump 3 submerged in the tank and sent to the second stage (secondary) pump 5. The liquefied gas is pressurized by the pump 5 to a pressure sufficient to deliver it as fuel or city gas for boilers and turbines, and the fuel gas vaporizer (vaporizer).
It is converted into vaporized gas by 4. In the vaporizer 4, the liquefied gas is vaporized by exchanging heat with the exhaust gas such as seawater or a boiler. Here, the pump 2 is a pump that sucks up seawater. The fuel gas evaporated in a storage tank (not shown) is a boil-off gas having a substantially atmospheric pressure, and is burned in the flare stack 8 or pressurized by the compressor 9 and sent out. Then, the high-pressure gas vaporized by the vaporizer 4 is sent by a pipeline to a power station at a remote place or a demand place such as a city gas station.

By the way, in the conventional liquefied gas supply system shown in FIG. 5, the second-stage pump 5 is driven by electric power using electric power. However, the second-stage pump 5, which is the main pump for feeding the liquefied gas under pressure, has a large flow rate and head, and as a result, the driving horsepower is increasing. Therefore, the motor for driving the second-stage pump 5 also consumes power of several hundreds to several thousands kW, and a high-voltage large-capacity power supply facility is required. Therefore, by using an expander (expansion turbine) pump that uses liquefied natural gas that is the self-liquid to be pumped, a so-called self-contained liquefied gas supply system that does not require external energy supply Is being considered.

The outline of a liquefied gas supply system using an expander pump as the second stage pump is as follows.
The gas vaporized by the vaporizer is supplied to the expander (expansion turbine) of the expander pump and is expanded to drive the second stage pump. The gas discharged from the expander, whose pressure is reduced, is supplied to the demand side as fuel gas for the city gas line or boiler. Further, the gas having a lower pressure is discharged to the boil-off gas line.
The boil-off gas is burned in a flare stack, or pressurized by a boil-off gas compressor, and supplied as fuel gas to a local pipeline or the like.

The use of a self-contained expander pump as the second-stage pump in the liquefied gas supply system and the structure of the expander pump are described in Japanese Patent Application No. 6-139535 by the present inventors. Japanese Patent Application No. 6-139
Details are disclosed in the '536 patent application.

[0006]

However, when the self-contained expander pump is used as the second stage pump of the liquefied gas supply system, the expansion turbine is expanded by the expansion of the high pressure gas in a steady operation state. Although the liquefied gas can be pressurized and pressure-fed with a directly connected pump by rotating it, there is a problem that the high-pressure gas that rotationally drives the turbine due to expansion does not exist at the time of its startup, so that it cannot be started.

The present invention has been made in view of the above-mentioned circumstances, and an object thereof is to provide a liquefied gas supply system capable of smoothly starting a self-contained expander pump.

[0008]

The first aspect of the present invention is as follows.
Liquefied gas storage tank, first stage pump for delivering liquefied gas from the storage tank, second stage pump for repressurizing the discharge liquid of the first stage pump, and vaporization of the discharge liquid of the second stage pump In the liquefied gas supply system, which comprises a vaporizer and the second-stage pump is driven by an expander using the vaporized gas, the second-stage pump is bypassed and the liquefied gas is fed from the first-stage pump to the vaporizer. A bypass pipe for supplying the gas, a line connecting the expander's back pressure line to a line at approximately atmospheric pressure via a mechanism that limits the flow rate, and a part or all of the gas from the carburetor bypasses the expander. And a line connected to the back pressure line via a mechanism for limiting the flow rate.

The second aspect of the present invention is to store liquefied gas.
Storage tank and first for delivering liquefied gas from the storage tank
Stage pump and a second stage for repressurizing the discharge liquid of the first stage pump
-Stage pump and vaporizer for vaporizing the liquid discharged from the second-stage pump
And the second-stage pump uses the vaporized gas.
Liquefied gas supply system driven by expander
In arm, the inlet valve and expander of the second stage pump
Open the adjustment mechanism of the back pressure line of the
After closing the second-stage pump outlet valve, bypassing the second-stage pump , liquefied gas from the first-stage pump to the vaporizer
And JoHiraku an adjusting mechanism of the bypass pipe for supplying supplies slowly vaporized gas to said expander, rotation of the second stage pump
Liquefaction gas from the second stage pump to the vaporizer
The adjustment mechanism of the main piping for supplying
The adjustment mechanism of the Y-pass pipe is gradually closed, and the discharge liquid of the second stage pump is
Mainly the vaporized gas passes through the vaporizer and the vaporized gas expands.
Drive the cylinder and further adjust the flow rate adjustment mechanism of the back pressure line.
As it opens, is the back pressure line at the atmospheric pressure line?
The second-stage port is closed by closing the flow rate adjustment mechanism
And performing the activation of the pump.

A third aspect of the present invention is to store liquefied gas.
Storage tank and first for delivering liquefied gas from the storage tank
Stage pump and a second stage for repressurizing the discharge liquid of the first stage pump
-Stage pump and vaporizer for vaporizing the liquid discharged from the second-stage pump
And the second-stage pump uses the vaporized gas.
Liquefied gas supply system driven by expander
In the pump, a pump separate from the first stage pump ,
A pipe for supplying liquefied gas to the vaporizer from the pump, the flow rate adjustment mechanism expander backpressure line substantially atmospheric 圧Ra Inn
Part of the vaporized gas from the vaporizer and the line connecting through
Or , flow the entire amount to the back pressure line by bypassing the expander.
And a line connected through a quantity adjusting mechanism .

Further, a fourth aspect of the present invention is to store a liquefied gas.
Storage tank and first for delivering liquefied gas from the storage tank
Stage pump and a second stage for repressurizing the discharge liquid of the first stage pump
-Stage pump and vaporizer for vaporizing the liquid discharged from the second-stage pump
And the second-stage pump uses the vaporized gas.
Liquefied gas supply system driven by expander
Liquefied gas storage by installing an auxiliary pump for starting
Liquefied gas is supplied from the tank to the vaporizer by the pump.
Air from the second stage pump and piping equipped with a flow rate adjustment mechanism
A pipe equipped with a flow rate adjusting mechanism connected to the vaporizer, and a line for connecting a part or all of the vaporized gas from the vaporizer to the back pressure line via the flow rate regulating mechanism by bypassing the expander.
It is characterized by having the following.

The fifth aspect of the present invention is to store liquefied gas.
Storage tank and first for delivering liquefied gas from the storage tank
Stage pump and a second stage for repressurizing the discharge liquid of the first stage pump
-Stage pump and vaporizer for vaporizing the liquid discharged from the second-stage pump
And the second-stage pump uses the vaporized gas.
Liquefied gas supply system driven by expander
In arm, the first stage by bypassing the second stage pump
Bypass piping that supplies liquefied gas from the pump to the vaporizer
And using the gas vaporized by the vaporizer,
It is characterized by activating the commander .

[0013]

[0014]

[0015]

[0016]

[0017]

[0018]

[0019]

[0020]

[0021]

[0022]

According to the present onset bright, when to start the second stage pump, it can be sent directly liquefied gas to the vaporizer by a bypass pipe from the first stage pump. Then, by setting the outlet pressure of the expander to about atmospheric pressure, the liquefied gas having a relatively low pressure of the first-stage pump is gasified by the vaporizer and pushed into the expander. Since the expander has substantially the atmospheric pressure at its outlet, a sufficient gas pressure is secured to start the expander, and the turbine starts rotating. When the expander is activated, the second-stage pump can pressurize the liquefied gas discharged from the first-stage pump, and the liquefied gas having a gradually higher pressure is pushed into the vaporizer. By gradually opening the adjusting valve of the main pipe of the second stage pump and gradually closing the adjusting valve of the bypass pipe, the flow of the liquefied gas on the pump side is changed to a steady state flowing through the main pipe. On the gas side, on the other hand, the operating mechanism is switched to a normal operating state by gradually squeezing the adjusting mechanism communicating with the atmospheric pressure and gradually opening the adjusting mechanism of the back pressure line.

According to another aspect of the present invention, a pump separate from the first-stage pump is provided, the liquefied gas is supplied from the pump to the vaporizer, and the expander back pressure line is brought to substantially atmospheric pressure. By holding, the liquefied gas pressurized by the separate relatively small pump is pushed into the vaporizer. The gas pressure vaporized by the vaporizer is low, but since the expander back pressure line is maintained at approximately atmospheric pressure, a sufficient gas pressure is secured for starting the expander. As a result, the expander is activated and the turbine speed gradually increases. At the same time, the second stage pump gradually increases its rotational speed, further pressurizes the liquefied gas discharged from the first stage pump and pushes it into the vaporizer, and the pressure of the vaporized gas vaporized by the vaporizer gradually rises. The higher the pressure of the vaporized gas, the higher the output of the expander and the higher the output of the pump. In this way, the second stage pump can be started.

Further, according to still another aspect of the present invention,
An auxiliary pump for starting is installed, and the liquefied gas is supplied from the liquefied gas storage tank to the vaporizer by the pump. As a result, the gas vaporized by the vaporizer can be supplied to the expander, and the expander can be activated. As the speed of the second-stage pump increases, the flow rate adjustment mechanism on the discharge side of the auxiliary pump is throttled, and the flow rate adjustment mechanism on the discharge side of the second stage pump is opened to gradually shift to a steady operating state. it can. Then, by adjusting the amount of the vaporized gas at the outlet of the vaporizer bypassing the expander and flowing to the back pressure line, the amount of vaporized gas according to the load of the second stage pump can be pushed into the expander.

Further, according to still another aspect of the present invention,
The expander can be started by providing a means for injecting another liquefied gas into the vaporizer or a means for supplying the vaporized gas to the expander. At this time, by connecting the back pressure line to the substantially atmospheric pressure line by opening the flow rate adjusting mechanism, sufficient pressure can be secured for starting the expander even when the inlet pressure of the expander is relatively low. When the turbine starts rotating and the second stage pump starts to move, the liquefied gas pressurized by the second stage pump is pushed into the vaporizer,
The pressure on the carburetor outlet side rises. This increases the output of the expander and the output of the second stage pump. In this cycle, the pump rotation speed gradually becomes steady, the pressure at the outlet side of the carburetor rises, and the exhaust gas from the expander is made substantially large by narrowing the flow rate adjustment mechanism of the line communicating with atmospheric pressure. Switch from the atmospheric pressure line to the gas delivery line side. As a result, the delivery pressure to the medium- and high-pressure gas delivery line header increases, and a steady operating state is achieved. By adjusting the flow rate adjusting mechanism of the bypass line of the expander, the expander output corresponding to the load required by the second stage pump can be obtained, and the surplus high-pressure gas can be directly delivered.

Further, according to still another aspect of the present invention,
A bypass pipe that bypasses the second-stage pump and supplies the liquefied gas from the first-stage pump to the carburetor is provided, and starts the expander using the gas vaporized by the carburetor. It is possible to provide a so-called self-contained liquefied gas supply system that does not require the above.

[0027]

EXAMPLES Hereinafter, with reference to the accompanying drawings actual施例of the present invention. In the drawings, the same reference numerals indicate the same or corresponding parts.

FIG. 1 shows a liquefied natural gas (LNG) supply system according to a first embodiment of the present invention. Liquefied natural gas (LNG) transported by an LNG tanker or the like is transferred and stored in the semi-underground liquefied gas storage tank 1. Then, LNG (liquefied gas) of liquid is generated by the first stage (primary) pump 3.
Is pumped up, pressurized by the second stage (secondary) pump 6, and sent to the vaporizer 4. The second stage pump 6 is driven by an expander (expansion turbine) 7. Vaporizer 4
The LNG (vaporized gas) that has been gasified at high pressure is regulated by the pressure regulating governor 11 and expanded in the expander 7 to rotationally drive the impeller of the turbine and drive the pump 6 directly connected to the turbine. .

The vaporized gas whose pressure is reduced by expansion in the expander 7 is used for city gas or the like from the back pressure line 12 connected to the expander outlet, through the medium-high pressure gas delivery line header 13 to a pipeline or the like. It is transmitted over a long distance. The liquefied gas that has been pumped under high pressure by the pump G is gasified by the vaporizer 4 and the pressure energy is used to drive the second-stage pump 6 by the expander 7. It is possible to take out gas at a pressure of. 30-70 kg / cm ² Medium- and high-pressure gas is delivered over a long distance, 10 kg / cm ² Low-pressure gas of a certain degree is delivered for short distances, and is used for city gas or fuel for thermal power plants, steelworks, and the like. Although not shown, this liquefied gas supply system includes various measuring devices and control devices for operating the entire system optimally.

In order to start this self-contained second stage pump, the piping and lines described below are provided. Here, a pipe through which liquid LNG (liquefied gas) flows is called a pipe, and a pipe through which a gas body LNG (vaporized gas) flows is called a line. The bypass pipe 14 that bypasses the second-stage pump and directly supplies the liquefied gas from the first-stage pump 3 to the vaporizer 4 is provided. The pipe 14 is provided with an adjusting valve 15 and a check valve 16 for adjusting the liquid flow rate by opening and closing. Further, a minimum flow pipe 17 is connected to the discharge side of the second stage pump 6, and is connected to the tank 1 via a regulating valve 18. The minimum flow pipe 17 is for preventing fuel loss and the like due to the shutoff operation of the pump, and is a pipe for allowing a minimum liquid flow to the pump even during the shutoff operation.

In the main pipe 19 to which the second stage pump 6 is connected, an inlet valve 29 is provided on the suction side, a check valve 20 and a flow rate adjusting valve 21 are provided on the discharge side, and a bypass pipe is provided beyond that. It merges with 14 and is connected to the inlet of the vaporizer 4.

The gas line on the outlet side of the vaporizer 4 bypasses the expander 7 and the back pressure line 1 of the expander 7.
2 has a bypass line 22 directly connected to it. The line 22 is equipped with an adjusting valve 23 for adjusting the gas flow rate. The back pressure line 12 connected to the outlet of the expander is provided with a regulating valve 24 and a check valve 25 for regulating the gas flow rate in the back pressure line 12. Further, the back pressure line 12 is connected to a line 27 that communicates with substantially atmospheric pressure, and the back pressure line 12 can be connected to a boil-off gas line 26 having substantially atmospheric pressure. A flow rate adjusting valve 28 is connected to the line 27.

These adjusting valves 15, 18, 21, 23,
Opening / closing of 24 and 28 is controlled by a command from a control device (not shown) to control the flow rates of the liquefied gas and the vaporized gas in the respective pipes and gas lines, and to control the flow and cutoff of these.

Next, the procedure for starting the second stage pump 6 will be described. Liquefied gas (LN
G) is stored and is pumped to the ground by the first stage pump 3.

First, the inlet valve 29 of the second stage pump 6 and the adjusting valve 18 of the minimum flow pipe 17 are opened. This allows
A minimum flow can be formed in the second stage pump 6. The adjusting valve 21 of the main pipe 19 is closed. Then, by gently opening the valve 15 of the bypass pipe 14 that directly supplies the pressurized liquid from the first-stage pump 3 to the carburetor 4 by bypassing the second-stage pump 6, the bypass pipe 14 transfers to the carburetor 4. Liquefied gas is pushed in. In the vaporizer 4, the liquefied gas is vaporized by heat exchange and the high-pressure vaporized gas is pushed out.

On the back pressure side of the expander 7, the control valve 25 of the back pressure line 12 is closed at the time of startup, and the control valve 28 of the line 27 communicating with the boil-off gas line 26 of substantially atmospheric pressure.
open. The adjusting valve 23 of the bypass line 22 is also closed so that the entire amount of the vaporized gas discharged from the vaporizer 4 enters the expander 7.

The gas vaporized by the vaporizer 4 enters the expander 7 from the pressure regulating governor 11 of the expander 7, expands, drives the turbine, and activates the second stage pump 6.
The back pressure line 12 of the expander 7 is connected to the boil-off gas line of substantially atmospheric pressure by opening the adjusting valve 28 of the line 27. Therefore, the gas pressure on the inlet side of the expander 7 at the time of startup is low, but the pressure of the back pressure line 12 is substantially atmospheric pressure, so that the required pressure of the expander 7 at the time of startup can be secured. The adjusting valve 24 of the back pressure line 12 is initially closed.

Gas is supplied into the expander 7, and the rotation speed of the pump 6 gradually increases. Pump 6 with this
The discharge pressure gradually increases and the adjustment valve 21 of the main pipe 19 is gradually opened, whereby the amount of liquid flowing through the main pipe 19 gradually increases and becomes the main flow. Along with this, the bypass piping 14
By gradually closing the adjusting valve 15 of 1, the start-up is completed and the second-stage pump 6 enters a steady operation state.

At the same time, on the gas side, based on the turbine speed of the expander 7, the regulating valve 28 of the line 27 connected to the line 26 of substantially atmospheric pressure is gradually closed, and the back pressure line 1
The adjusting valve 24 of No. 2 is gradually opened. At the same time, the opening degree of the adjusting valve 23 of the gas bypass line 22 is adjusted so that the gas having a predetermined pressure is supplied to the pressure regulating governor 11 of the expander 7. As described above, when the second-stage pump 6 is started, as the second-stage pump 6 is brought into an appropriate rotating state, the adjusting valve 28 connecting the back pressure line 12 having a substantially atmospheric pressure is gradually closed. By controlling the flow rate of the gas flowing out to the boil-off gas line 26 and opening the adjusting valve 24 that limits the flow rate of the back pressure line 12, the expander 7 is smoothly shifted to the rated operating state. Although the amount of gas entering the expander 7 increases when the second-stage pump 6 is started, the gas can flow into the back pressure line 12 by bypassing the expander 7 by opening the adjusting valve 23 of the gas bypass line 22. Therefore, the start-up can be smoothly performed by treating the excess gas.

As described above, when activating the second-stage pump, by bypassing the second-stage pump from the first-stage pump and sending the liquefied gas directly to the vaporizer 4, a large pressure in the second-stage pump is obtained. The gas for starting the expander can be supplied without any loss or the like. By setting the outlet pressure of the expander 7 to approximately atmospheric pressure, even if the inlet pressure of the expander is as low as the discharge pressure of the first-stage pump (usually 10 kg / cm ² ), the expander 7 that is sufficient for start-up The gas pressure can be secured. By providing the expander 7 with the bypass line 22, the flow rate of the gas flowing into the expander can be adjusted and the output of the expander can be controlled. Further, when the outlet pressure of the expander 7 is started at substantially atmospheric pressure, the gas pressure of the expander becomes excessive with the pump started, but the regulating valve 28 of the line 27 communicating with the atmospheric pressure is gradually closed. By gradually opening the regulating valve 24 of the back pressure line 12 and sending gas to the pipeline side, the outlet pressure of the expander can be controlled to a prescribed pressure, and a steady operating state can be achieved. .

FIG. 2 shows a liquefied natural gas supply system according to a second embodiment of the present invention. The basic configuration of this embodiment is shown in FIG.
The same parts as those of the first embodiment shown in FIG.

In this embodiment, a pump 30 and a tank 32, which are separate from the first stage pump 3, are provided. The pump 30 is a pump driven by an electric motor, and the piping 3
The liquefied gas stored in the tank 32 via the vaporizer 4
Supply to. The main pipe 19 of the second-stage pump 6 and the pipe 31 of the auxiliary pump 30 are joined together as shown in the drawing and connected to the inlet side of the vaporizer 4. A check valve 34, an inlet valve 35, and a regulating valve 33 are connected to the pipe 31.

When starting the second stage pump, the pipe 31
The inlet valve 35 is opened and the auxiliary pump 30 is started. Then, by gradually opening the adjusting valve 33, the liquefied gas in the tank 32 is pumped up and is pushed into the vaporizer 4 through the pipe 31. The configuration on the outlet side of the vaporizer 4 is the same as that of the above-described embodiment, and the outlet side of the expander 7 is in communication with the line 26 of substantially atmospheric pressure. Therefore, even if the pressure of the liquefied gas pumped up by the relatively small auxiliary pump 30,
At the inlet side of the expander 7, sufficient pressure is secured to start the expander. When the expander 7 is activated, the second-stage pump starts rotating, and the liquefied gas pumped up from the storage tank 1 passes through the pipe 19 and is pushed into the vaporizer 4. As a result, the pressure of the vaporized gas on the outlet side of the vaporizer 4 increases and the pressure of the expander 7 increases. Then, the output of the second stage pump 6 increases, and the feed pressure of the liquefied gas can be further increased. In this way, the expander 7 and the second stage pump 6 shift to a steady operating state. On the liquid side, the auxiliary pump 30
The flow rate adjusting valve 33 of the pipe 31 communicating with is gradually reduced, and the adjusting valve 21 of the main pipe 19 of the second stage pump 6 is gradually opened to shift to the steady state. Similarly, on the gas side after the outlet of the vaporizer 4, the flow rate adjusting valve 28, which also communicates with the atmospheric pressure, is gradually closed, and the adjusting valve 24 of the back pressure line 12 is gradually opened, so that the exhaust gas from the expander 7 is discharged. It is sent to the long-distance delivery pipeline via the high-pressure gas delivery line header 13. Further, by adjusting the opening degree of the adjusting valve 23 of the bypass line 22 that bypasses the expander 7,
It is possible to feed as much vaporized gas as the output of the second stage pump 6 into the expander 7.

FIG. 3 shows a liquefied natural gas supply system according to a third embodiment of the present invention. The configuration of this embodiment is also the above-described second.
The configuration is almost the same as that of the embodiment, and the same portions are denoted by the same reference numerals and the description thereof is omitted.

This embodiment is different from the second embodiment in that the second embodiment
In the embodiment, the auxiliary pump 30 pumps up the liquefied gas stored in the separate tank 32 and supplies the liquefied gas to the carburetor 4, whereas in the present embodiment, the separate tank is not provided, and the storage tank 1 The auxiliary pump 30 directly pumps up. Therefore, the starting operation of the second stage pump 6 is the same as that of the second embodiment described above.

FIG. 4 shows a liquefied natural gas supply system according to a fourth embodiment of the present invention. In the present embodiment, the liquefied gas is supplied from the separate tank 32 to the vaporizer 4 by using the auxiliary pump in the second embodiment described above, while the pressurized liquefied gas is evaporated from the separate tank 36. It is adapted to be supplied to the container 4. This pipe 31 is connected to the flow rate adjusting valve 33 and the check valve 3
The provision of 4 is the same as in the second embodiment. The pressurized liquefied gas can be supplied to the pipe 31 by adding the pressurized gas to the liquid surface of the tank 36 from the introduction hole 37. This pressure gas may be a so-called self-liquid gas obtained by vaporizing liquefied natural gas, or another different type of gas source may be used. Therefore, the procedure for starting the second-stage pump 6 is the same as in the second embodiment described above.

A pipe 38 is connected to the outlet side of the carburetor 4, and a flow rate adjusting valve 39 and a check valve 40 are provided in the pipe 38.
The vaporized gas may be supplied by a separate pressurized gas source. Even in this case, the second-stage pump 6 can be pressurized as in the above-described embodiments. Also, the pipe 31
Alternatively, when a liquefied gas is pushed from 38 to the inlet side of the expander 7 and a sufficiently high pressure necessary for starting is obtained, the outlet side of the expander 7 does not necessarily have to be atmospheric pressure. In such a case, the system configuration can be simplified by omitting the line 27.

Incidentally, the above-described embodiment is a liquefied natural gas (LN
G), but liquefied propane gas (LP
Needless to say, the gist of the present invention can be applied to other liquefied gases such as G).

[0049]

As described above, according to the present invention, the expander pump can be smoothly started in the liquefied gas supply system in which the pump for pressurizing and delivering the liquefied gas is driven by the expander using its own liquid. Therefore, according to the present invention, it is possible to operate the self-contained liquefied gas supply system using the expander pump to achieve the original purpose of resource saving and energy saving.

[Brief description of drawings]

FIG. 1 is an explanatory diagram of a liquefied natural gas supply system according to a first embodiment of the present invention.

FIG. 2 is an explanatory diagram of a liquefied natural gas supply system according to a second embodiment of the present invention.

FIG. 3 is an explanatory diagram of a liquefied natural gas supply system according to a third embodiment of the present invention.

FIG. 4 is an explanatory diagram of a liquefied natural gas supply system according to a fourth embodiment of the present invention.

FIG. 5 is an explanatory diagram of a conventional liquefied natural gas supply system.

[Explanation of symbols]

1 storage tank 3 first stage pump 4 vaporizer 6 Second stage pump 7 Expander 12 Back pressure line 14 Bypass piping 15,18,21,23,24,28 Regulator valve 19 Main piping 22, 27 Bypass line 26 Approximate atmospheric pressure line

─────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-59-188005 (JP, A) JP-A-2-229998 (JP, A) Fukuikai-2-22500 (JP, U) (58) Field (Int.Cl. ⁷ , DB name) F17C 9/02-9/04 F17D 1/02

Claims (5)

(57) [Claims] 1. A liquefied gas storage tank, a first-stage pump that delivers liquefied gas from the storage tank, a second-stage pump that repressurizes the liquid discharged from the first-stage pump, and a second-stage pump. A liquefied gas supply system that is driven by an expander that uses the vaporized gas, wherein the second-stage pump bypasses the second-stage pump and Bypass piping that supplies liquefied gas to the vaporizer, a line that connects from the back pressure line of the expander to a line that is at about atmospheric pressure via a mechanism that limits the flow rate, and a part or all of the gas from the vaporizer A line for connecting the back pressure line to the back pressure line via a mechanism that restricts the flow rate by bypassing the expander. 2. A liquefied gas storage tank, a first-stage pump that delivers liquefied gas from the storage tank, a second-stage pump that repressurizes the discharge liquid of the first-stage pump, and a second-stage pump. In the liquefied gas supply system, which comprises a vaporizer for vaporizing the discharge liquid, and the second-stage pump is driven by an expander using the vaporized gas, an inlet valve of the second-stage pump and a back pressure of the expander. By-pass piping that opens the adjusting mechanism to the line of approximately atmospheric pressure and closes the second-stage pump outlet valve, then bypasses the second-stage pump and supplies liquefied gas from the first-stage pump to the vaporizer. of the adjustment mechanism and JoHiraku supplies slowly vaporized gas to said expander, Xu adjustment mechanism of main pipe for supplying liquefied gas to the vaporizer from the second-stage pump with the rotation speed of the second stage pump increases When open Wherein the adjusting mechanism of the bypass pipe Xu closed, vaporization gas through the vaporizer discharge liquefied gas of the second stage pump is mainly drives the expander, further, the flow rate adjusting mechanism of the back pressure line opens A method for operating a liquefied gas supply system, characterized in that the second-stage pump is started by closing a flow rate adjusting mechanism connected to the approximately atmospheric pressure line from the back pressure line. 3. A liquefied gas storage tank, a first-stage pump that delivers liquefied gas from the storage tank, a second-stage pump that repressurizes the discharge liquid of the first-stage pump, and a second-stage pump. A liquefied gas supply system that is composed of a vaporizer that vaporizes the discharge liquid, wherein the second-stage pump is driven by an expander that uses the vaporized gas, and a pump that is separate from the first-stage pump, A pipe that supplies the liquefied gas from the pump to the vaporizer, a line that connects the expander back pressure line to the approximately atmospheric pressure line via a flow rate adjustment mechanism, and an expander for a part or all of the vaporized gas from the vaporizer. A liquefied gas supply system comprising a line for bypassing and connecting to a back pressure line via a flow rate adjusting mechanism. 4. A liquefied gas storage tank, a first-stage pump that delivers liquefied gas from the storage tank, a second-stage pump that repressurizes the discharge liquid of the first-stage pump, and a second-stage pump. The second stage pump is a liquefied gas supply system driven by an expander that uses the vaporized gas, and a second auxiliary pump is installed in the liquefied gas supply system. A pipe having a flow rate adjusting mechanism for supplying the liquefied gas to the vaporizer by a pump, a pipe having a flow rate adjusting mechanism connected to the vaporizer from the second-stage pump, and a part of the vaporized gas from the vaporizer or A liquefied gas supply system comprising: a line that bypasses the expander and connects to the back pressure line through a flow rate adjusting mechanism. 5. A liquefied gas storage tank, a first stage pump for delivering the liquefied gas from said storage tank, said a second stage pump re-pressurizing the discharge liquid in the first stage pump, discharge of the second stage pump In a liquefied gas supply system driven by an expander using the vaporized gas, the second stage pump comprises a vaporizer for vaporizing liquid, and the second stage pump is vaporized from the first stage pump. A liquefied gas supply system comprising a bypass pipe for supplying a liquefied gas to the container, and activating the expander using the gas vaporized by the vaporizer.