JP2005330979A - Liquefied gas supply method and liquefied gas supply device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquefied gas supply method and a liquefied gas supply device by which a prescribed liquid head pressure can be effectively secured and mounting cost can be effectively reduced without mounting a reservoir at a high position even if a liquid level is lowered to the bottom direction. <P>SOLUTION: The liquefied gas supply method is equipped with a liquefied gas taking out process for taking the liquefied gas out of a reservoir in which liquefied gas is stored in a liquid state, a vaporizing process for converting into a gaseous state the liquefied gas in a liquid state taken out by the liquefied gas taking out process, a gas pressure accumulating process for pressure accumulation of a gas in a gaseous state, and a gas supply process for supplying to the outside the gas pressure accumulated in the gas pressure accumulating process. The gas pressure accumulated in the gas pressure accumulating process is supplied in the reservoir. By utilizing gas pressure supplied in the reservoir, the liquefied gas taking out process can be carried out. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a liquefied gas supply method and a liquefied gas supply apparatus for supplying various liquefied gases to the outside in a liquid state or in a gas state, and in particular, supplies a low-temperature liquefied gas such as LNG (liquefied natural gas) to the outside. The present invention relates to a liquefied gas supply method and a liquefied gas supply device used for the purpose.

  In recent years, natural gas has been attracting attention as a fuel for automobiles because it is more environmentally friendly than conventional fuels such as gasoline and light oil. In some areas, there are gas stations that supply natural gas to automobiles. It is being built. As shown in FIG. 2, the liquefied gas supply apparatus or the liquefied gas supply method in this gas station includes a storage tank 50 in which liquefied natural gas (LNG) is stored, and a liquefied natural gas stored in the storage tank 50. A pump 51 to be taken out in a liquid state, a carburetor 52 that vaporizes and converts the liquefied natural gas taken out by the pump 51 into a gaseous state (heat exchange), and an accumulator that accumulates the gas that has been brought into a gaseous state by the vaporizer 52 A gas unit 53 and a dispenser 54 for supplying the gas stored in the gas storage unit 53 to the (natural gas) vehicle V are provided. The storage tank 50 is connected to a proximal end of a supply pipe 57 to which a manual valve 55 and an automatic valve 56 are attached, and liquefied natural gas is stored in the storage tank 50 from the LNG lorry T through the supply pipe 57. The The pump 51 sucks the liquefied natural gas in the storage tank 50 in a liquid state and transfers it to the downstream side. The vaporizer 52 vaporizes the liquefied natural gas transferred by the pump 51 by heating (heat exchanging) until it reaches a boiling point by heating means such as warm water, a heater, or atmospheric heat. Further, as described above, the gas storage unit 53 stores the gas vaporized by the vaporizer 52, and a plurality of gas storage containers 60 connected to each other via pipes 58 and 59. It has. An open / close valve 62 is attached to the pipeline 61 piped upstream of the gas storage unit 53, and an open / close valve 64 is also attached to the downstream pipeline 63. The downstream pipe line 63 is connected to the dispenser 54, and the natural gas accumulated in the gas accumulator unit 53 passes through the nozzle 65 constituting the dispenser 54. Gas) is supplied to the automobile V. The pump 51 is connected to the storage tank 50 via a pipe 66, and the evaporated vaporized gas generated by driving the pump 51 is returned to the storage tank 50. The storage tank 50 is connected to a BOG tank 68 via a pipe line 67, and the vaporized vapor generated in the storage tank 50 is stored in the BOG tank 68. The vaporized gas stored in the BOG tank 68 is recovered and utilized by a BOG recovery device (not shown) or released to the atmosphere via a diffusion pipe.

  By the way, when the liquefied gas is taken out from the storage tank 50 by driving the pump 51, the pressure inside the pump 51 or the suction pipe falls below an allowable amount, thereby lowering the boiling point of the liquefied gas and vaporizing the liquefied gas. High risk (cavitating cavitation). For this reason, the pump 51 used in the liquefied gas supply apparatus must secure a pump-specific NPSH (effective positive suction head) from the viewpoint of preventing such cavitation. Therefore, conventionally, in order to ensure the liquid head pressure between the storage tank 50 and the pump 51, the storage tank 50 is installed at a position higher than the ground (the installation position of the pump 51) (or the pump 51 is buried underground). Must. However, in order to install the storage tank 50 at a high position or embed the pump 51 in the basement in this way, the foundation work becomes large and the installation cost becomes high. In particular, depending on the installation position of the storage tank 50, when the liquid level of the liquefied gas stored therein is high, the liquefied gas can be taken out, but cannot be taken out as the liquid level becomes low. It will not be possible to effectively use the capacity.

  Therefore, the present invention has been proposed in order to solve the problems of the above-described conventional liquefied gas supply method or liquefied gas supply device, and the liquid level can be maintained without installing the storage tank at a high position. Provided is a novel liquefied gas supply method and a liquefied gas supply apparatus capable of effectively ensuring a predetermined liquid head pressure and effectively reducing installation costs even when the liquid is lowered to the bottom. It is for the purpose.

  In order to achieve the above-described object, the first invention (the invention described in claim 1) relates to a liquefied gas supply method, and the liquefied gas is liquefied from a storage tank in which the liquefied gas is stored in a liquid state. Liquefied gas extraction step to be taken out in a state, a vaporization step to make the liquid liquefied gas taken out in the liquefied gas take-out step into a gaseous state, a gas pressure accumulation step to accumulate the gas in the gaseous state, and this gas accumulation pressure A gas supply step of supplying the gas accumulated in the process to the outside, supplying the gas accumulated in the gas accumulation step into the storage tank, and using the gas pressure supplied in the storage tank A liquefied gas extraction step is performed.

  Moreover, 2nd invention (invention of Claim 2) concerns on the liquefied gas supply apparatus, Comprising: The storage tank which stores liquefied gas in a liquid state, and takes out the said liquefied gas from this storage tank in a liquid state Liquefied gas take-out means, vaporizing means for bringing the liquefied gas taken out by the liquefied gas take-out means into a gaseous state, gas accumulating means for accumulating the gas in the gaseous state, and gas accumulated by the gas accumulating means Supply means for supplying the gas to the outside, wherein the gas accumulating means and the storage tank are connected via a conduit for supplying the gas accumulated in the gas accumulating means into the storage tank. To do.

  The third invention (the invention according to claim 3) is characterized in that, in any of the first and second inventions, the storage tank is buried underground.

In each of the above inventions, the liquefied gas is not limited to liquefied natural gas (LNG), but is liquefied by cooling of O ₂ gas, N ₂ gas, Ar gas, H ₂ gas, He gas, CO ₂ gas, or the like. Any low temperature liquefied gas can be stored.

  In the first and second inventions (inventions according to claims 1 and 2), the gas accumulated in the gas accumulating step is supplied into the storage tank, and the gas pressure supplied into the storage tank is used. The liquefied gas extraction step is performed, or the gas accumulating means and the storage tank are connected via a pipeline for supplying the gas accumulated in the gas accumulating means into the storage tank. It is not necessary to arrange at the position, and even when the liquid level of the liquefied gas stored in the storage tank is lowered to the bottom direction, the liquid head pressure can be sufficiently secured by the gas pressure. Therefore, according to this invention, the installation cost of a storage tank can fully be suppressed. Moreover, according to these inventions, it is possible not only to install the storage tank at a low position from the ground, but also to embed it underground.

  Moreover, according to the liquefied gas supply device in which the storage tank is buried underground as in the third invention (invention of claim 3), the instability of neighboring residents who visually observe the storage tank installed on the ground In addition to being able to eliminate the problem, it is possible to prevent the air from being influenced by the temperature of the atmosphere, and to effectively prevent the risk that the BOG abnormally occurs and the pressure in the storage tank becomes abnormally high.

  Hereinafter, the best mode for carrying out the present invention will be described in detail with reference to the drawings. First, a liquefied gas supply apparatus will be described in detail, and then a liquefied gas supply method will be described.

  The liquefied gas supply apparatus according to this embodiment is an application of the present invention to a gas station used for supplying natural gas to a natural gas vehicle. As shown in FIG. The storage tank 1 is provided with a pressurizing pump 4 connected via a first pipe line 2 and a second pipe line 3. The storage tank 1 is a container in which liquefied natural gas (LNG) is stored, and its periphery is covered with a heat insulating material 5. The storage tank 1 is installed on the ground or buried underground, and is connected to a supply line 6 for supplying liquefied natural gas to the storage tank 1 from an LNG lorry (not shown). The supply line 6b supplies liquefied natural gas into the storage tank 1 from above. The supply line 6a is connected to the bottom of the storage tank 1 and supplies LNG to the storage tank 1 from below.

  The pressurizing pump 4 sucks the liquefied natural gas in the storage tank 1 in a liquid state and transfers it to the downstream side. In this embodiment, the pressurizing pump 4 is constituted by a reciprocating pump. The pressurizing pump 4 is a liquefied gas take-out means constituting the present invention. Further, the pressurizing pump 4 is connected to the storage tank 1 via the second pipe 3 as described above. The second pipe 3 is piped to return the gas generated in the pressure pump 4 to the storage tank 1. The pressurizing pump 4 is connected to the vaporizer 8 via the third pipe line 7. The vaporizer 8 is a vaporization means constituting the present invention, and heats the liquefied natural gas transferred to the downstream side by the pressurizing pump 1 until the boiling point is reached by a heating means such as warm water, a heater, or atmospheric heat ( It is vaporized by heat exchange). A first check valve 9 is attached in the middle of the third pipe line 7 to prevent the natural gas vaporized by the vaporizer 8 from flowing backward in the direction of the pressure pump 4. doing.

  The vaporizer 8 is connected to a gas storage device 11 through a fourth pipe 10. This gas accumulator 11 is a gas pressure accumulating means constituting the present invention, and accumulates the natural gas vaporized in the vaporizer 8. A second check valve 12 is attached in the middle of the fourth pipe 10 to prevent the backflow of natural gas accumulated in the gas accumulator 11. The gas accumulator 11 is connected to the dispenser 14 via the fifth conduit 13. The dispenser 14 is a supply means constituting the present invention, and supplies the natural gas accumulated in the gas storage device 11 to a natural gas vehicle (not shown). A third check valve 15 is attached in the middle of the fifth pipe 13 to prevent the natural gas from flowing back from the dispenser 14 to the gas storage device 11. In addition, the dispenser 14 is roughly constituted by a device main body 14a and a gas supply nozzle 14b, and the device main body 14a has a measuring unit for measuring a gas supply amount (discharge amount) and a display unit for displaying the supply amount. Etc. are provided.

  The gas storage device 11 is connected to the storage tank 1 through a sixth pipe line 16. In other words, the liquefied gas supply device according to this embodiment is configured such that the natural gas accumulated in the gas accumulator 11 is supplied to the storage tank 1. A first opening / closing valve 17 is attached to the middle portion of the sixth pipeline 16 for supplying the natural gas to the storage tank 1. In the storage tank 1, a pressure gauge 18a for measuring the pressure in the storage tank 1 and a liquid level gauge 18b for measuring the liquid level of the liquefied natural gas in the storage tank 1 are arranged, respectively. The total gauge 18a, the liquid level gauge 18b, the first on-off valve 17 and the second on-off valve 23 described later are connected to each other via a control device (not shown) as indicated by a dotted line in FIG.

  On the other hand, the storage tank 1 is connected to a BOG heater 20 via a seventh pipe line 19, and this BOG heater 20 is connected to a cushion tank 22 via an eighth pipe line 21. ing. As will be described later, when the evaporated vaporized gas is generated in the storage tank 1, the seventh pipe line 19 circulates when the vaporized vaporized gas reaches a predetermined pressure or higher. It is a pipeline. A second opening / closing valve 23 is attached to a middle portion of the eighth pipe line 21 connecting the BOG warmer 20 and the cushion tank 22, and the second opening / closing valve The valve 23 is connected to the first opening / closing valve 17, the pressure gauge 18a, and the liquid level gauge 18b as shown by dotted lines in FIG. 1 and to a control device (not shown). The cushion tank 22 is connected to an odorizing device 25 through a ninth conduit 24. This odorizing device 25 smells the evaporated gas and facilitates confirmation when it leaks out. The odorizing device 25 is connected to a BOG compressor 27 via a tenth pipe line 26, and further, the BOG compressor 27 is connected to the gas accumulator 11 via an eleventh pipe line 28. It is connected. A fourth check valve 29 is attached to the middle of the eleventh pipe line 28, and the natural gas accumulated in the gas accumulator 11 flows backward in the direction of the BOG compressor 27. To prevent that.

  Hereinafter, the method of supplying the liquefied gas will be described in the order of steps while explaining the operation of the liquefied gas supply apparatus according to the above-described embodiment.

  First, when the pressurizing pump 4 is driven, the liquefied natural gas stored in the storage tank 1 is taken out through the first pipe line 2 in a liquid state (liquefied gas taking out step) and taken out. The liquefied natural gas is made into a gas state (vaporized) by the vaporizer 8 (vaporization step). The vaporized natural gas is accumulated in the gas accumulator 11 (gas accumulating step), and the natural gas accumulated in the gas accumulator 11 is operated by the gas supply nozzle 14 b constituting the dispenser 14. Thus, the gas is supplied to a natural gas vehicle (not shown) (gas supply step). At this time, if the conditions in the storage tank 1 measured by the pressure gauge 18a and the liquid level gauge 18b do not satisfy a predetermined condition (reference value or threshold value) determined in advance, The first open / close valve 17 is opened, whereby the natural gas accumulated in the gas accumulator 11 flows into the storage tank 1 through the sixth pipeline 16 and is stored in the storage tank 1. The pressure increases. Therefore, even when the liquid level of the liquefied natural gas in the storage tank 1 is lowered by driving the pressurizing pump 4 and the internal pressure or the liquid level is lowered, it is possible to ensure a sufficient liquid head pressure. The occurrence of cavitation can be effectively prevented. The step of supplying the natural gas from the gas storage device 11 into the storage tank 1 is performed regardless of the driving of the pressurizing pump 4, and the liquid level of the liquefied natural gas stored in the storage tank 1. If the condition in the storage tank 1 measured by the pressure gauge 18a and the liquid level gauge 18b is less than the reference value or threshold value, the first on-off valve 17 is opened. Is done. Therefore, the storage tank 1 can be installed at a position (for example, underground) lower than the installation position of the pressure pump 4.

  On the other hand, when the condition in the storage tank 1 exceeds the reference value or threshold value, the first opening / closing valve 17 is not opened (is closed when opened), and the second The open / close valve 23 is opened. That is, when the pressure in the storage tank 1 rises above a reference value or threshold value, the second open / close valve 23 is opened so that the vaporized gas is allowed to flow into the BOG warmer 20, cushion. It passes through the tank 22 and the BOG compressor 27 and flows into the gas accumulator 11. That is, in the liquefied gas supply apparatus according to this embodiment, when the condition in the storage tank 1 is a predetermined condition due to the generation of evaporated vaporized gas, the natural gas in the gas storage device 11 is supplied into the storage tank 1. Needless to say, since it is possible to ensure a sufficient liquid head pressure, if the first on-off valve 17 is not opened and the predetermined condition is not satisfied, the first on-off valve 17 is It is intended to open and secure liquid head pressure.

  As described above, according to the liquefied gas supply apparatus according to the above-described embodiment and the above-described liquefied gas supply method, the storage tank 1 does not need to be arranged at a high position, and the liquefied gas stored in the storage tank 1 can be stored. Even when the liquid level is lowered to the bottom, the liquid head pressure can be sufficiently secured by the gas pressure. Therefore, the installation cost of the storage tank 1 can be sufficiently suppressed. In addition, according to the liquefied gas supply apparatus according to this embodiment, the storage tank 1 can be buried underground. Thus, when the storage tank 1 is buried underground, it is installed in an exposed state on the ground. Not only can the anxiety of neighboring residents who visually observe the stored storage tank 1 be eliminated, but it can also be prevented from being influenced by the temperature of the atmosphere, and BOG abnormally occurs and the pressure in the storage tank 1 becomes abnormally high Risk can be effectively prevented.

  In the liquefied gas supply device described in the above embodiment, gas is stored through the pressurizing pump 4 and the vaporizer 8 in the gas storage step for storing gas in the gas storage device 11, but the present invention is not limited thereto. In the gas storage step to be configured, gas may be stored in the gas storage device 11 via the BOG compressor 27. Further, in the liquefied gas supply apparatus described in the above embodiment, the present invention is applied to a gas station used for supplying natural gas (NG) to a natural gas vehicle. Not only those applied to such gas stations, but also those used to supply other liquefied gas (low-temperature liquefied gas) to the outside, or those filled in containers or the like may be used.

It is a flow sheet which shows the liquefied gas supply device concerning an embodiment. It is a flow sheet which shows the conventional liquefied gas supply device.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Storage tank 4 Pressure pump 8 Vaporizer 11 Gas storage 14 Dispenser 16 6th pipe line 17 1st on-off valve 23 2nd on-off valve

Claims (3)

A liquefied gas extraction step for extracting the liquefied gas in a liquid state from a storage tank in which the liquefied gas is stored in a liquid state;
A vaporization step in which the liquid liquefied gas taken out in this liquefied gas take-out step is in a gaseous state;
A gas pressure accumulating step for accumulating the gas in a gas state;
A gas supply step of supplying the gas accumulated in this gas pressure accumulation step to the outside,
A method of supplying a liquefied gas, characterized in that the gas accumulated in the gas accumulating step is supplied into the storage tank, and the liquefied gas extraction step is performed using the gas pressure supplied into the storage tank. A storage tank in which liquefied gas is stored in a liquid state;
Liquefied gas extraction means for extracting the liquefied gas from the storage tank in a liquid state;
Vaporizing means for bringing the liquefied gas extracted by the liquefied gas extracting means into a gaseous state;
A gas accumulating means for accumulating the gas in a gas state;
A supply means for supplying the gas accumulated by the gas pressure accumulation means to the outside,
The liquefied gas supply device, wherein the gas accumulating means and the storage tank are connected via a pipeline for supplying the gas accumulated by the gas accumulating means into the storage tank. The liquefied gas supply device according to claim 1, wherein the storage tank is buried underground.