JP2005351299A - Fuel gas feeding apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fuel gas feeding apparatus capable of feeding a fuel gas with a specified pressure to high-pressure gas consuming sources such as a turbine cogenerator by using a lower self-consuming power. <P>SOLUTION: This fuel gas feeding apparatus comprises a tank 1 storing a liquefied fuel gas carried by a tank lorry TL and an evaporator 3 evaporating the liquefied fuel gas to the fuel gas. The fuel gas obtained after the liquefied fuel gas from the tank 1 is evaporated by the evaporator 3 is fed to the gas consuming sources 5, 6, 15 and 17 including the high-pressure gas consuming source 4. The apparatus also comprises a hydraulic pressure pump feeding the liquefied fuel gas from the tank 1 to the evaporator 3 after pressurizing. Hot water and steam obtained by collecting exhaust heat from the high-pressure gas consuming source 4 by a heat exchanger 12 are fed to the evaporator 3. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention includes a tank that stores liquefied fuel gas conveyed by a tank lorry, and an evaporator that vaporizes the liquefied fuel gas into fuel gas, and the fuel gas after the liquefied fuel gas from the tank is vaporized by the evaporator The present invention relates to a fuel gas supply facility configured to supply gas to a gas consumption source including a high-pressure gas consumption source.

For example, liquefied natural gas (hereinafter referred to as LNG), which is an example of liquefied fuel gas, is transported over the sea by a tanker and carried to a receiving terminal, and then transported to a rural area by a tanker truck, where it is an example of fuel gas. It is vaporized by natural gas and supplied to gas consumption sources such as factories and households.
Conventionally, a fuel gas supply facility in that region has been used in many cases as shown in FIG. 3 (since no suitable patent document is found, this is illustrated and described).
In the description of the conventional facility shown in FIG. 3, components used in the fuel gas supply facility of the present invention to be described later and components having the same action are denoted by the same reference numerals and a part of the description is omitted. To do.

A conventional fuel gas supply facility includes an LNG tank 1 that stores LNG conveyed by a tank truck TL, an evaporator 3 that vaporizes the LNG into natural gas, and the like, for example, 0.4 to 0.6 MPa. The LNG stored in the LNG tank 1 is vaporized to 0.4 to 0.6 MPa natural gas by the evaporator 3 under the pressure of
The natural gas after the vaporization is once stored in the auxiliary tank 13 and then appropriately reduced as necessary, and the boiler 15 which is an example of a medium pressure or low pressure gas consumption source, or a gas appliance for general household use. 17 or the like.
However, in the turbine cogeneration system 4 which is an example of a high-pressure gas consumption source, for example, 1.5 to 2.0 MPa of natural gas is required. The compressor 14 is connected to the downstream side of the auxiliary tank 13, and is pressurized to 1.5 to 2.0 MPa by the compressor 14 and supplied to the combustor 8 of the turbine cogeneration apparatus 4.
Further, the heat required for the evaporator 3 to vaporize the liquefied fuel gas is supplied by a heat source from an intermediate pressure or low pressure gas consumption source such as the boiler 15.

  In such a conventional fuel gas supply facility, for example, when generating 2000 kW of power using the turbine cogeneration system 4, the power consumption of the compressor 14 is about 100 kW, and approximately 5% of the power is consumed by itself. become.

  The present invention pays attention to such a current situation, and its purpose is to achieve a desired pressure with a lower self-consumption power than in the past, for a high-pressure gas consumption source such as the turbine cogeneration system 4. A fuel gas supply facility capable of supplying fuel gas is provided.

  Further, in the conventional fuel gas supply facility, the heat required when the evaporator 3 vaporizes the liquefied fuel gas is supplied by, for example, hot water or steam from an intermediate pressure or low pressure gas consumption source such as the boiler 15. If you do, you will consume about 3% of the fuel yourself.

  The present invention pays attention to such a current situation, and an object of the present invention is, for example, to supply a desired heat to the evaporator 3 with a self-consumption fuel lower than that of the conventional fuel gas at a desired pressure. The fuel gas supply equipment which can supply is supplied.

  A first characteristic configuration of the present invention includes a tank that stores liquefied fuel gas conveyed by a tank lorry, and an evaporator that vaporizes the liquefied fuel gas into fuel gas. The liquefied fuel gas from the tank is supplied by the evaporator. A fuel gas supply facility configured to supply the vaporized fuel gas to a gas consumption source including a high-pressure gas consumption source, and pressurizes the liquefied fuel gas from the tank and supplies it to the evaporator There is a hydraulic pump.

  According to the first characteristic configuration of the present invention, the liquefied fuel gas from the tank that stores the liquefied fuel gas is provided with the hydraulic pump that pressurizes the liquefied fuel gas and supplies it to the evaporator. Since the gas is pressurized and pressurized by a hydraulic pump in a liquid state, the pressure can be increased more efficiently than by pressurizing and boosting in the gas state as before, and then vaporized by an evaporator to be desired. Since the fuel gas having the pressure is obtained, the fuel gas having the desired pressure can be supplied to the high-pressure gas consumption source with lower self-power consumption than in the past.

  According to a second characteristic configuration of the present invention, the gas consumption source includes an intermediate pressure or low pressure gas consumption source, and the fuel gas after being vaporized by the evaporator with respect to the intermediate pressure or low pressure gas consumption source is decompressed. To supply.

According to the second characteristic configuration of the present invention, the gas consumption source includes not only the above-described high-pressure gas consumption source but also the medium-pressure or low-pressure gas consumption source. A medium-pressure or low-pressure fuel gas can also be supplied to the tank.
And, when supplying the fuel gas to the medium pressure or low pressure gas consumption source, it is only necessary to depressurize the high pressure fuel gas after being vaporized by the evaporator. Thus, the medium or low pressure fuel gas can be reliably supplied to the gas consumption source.

  In a third characteristic configuration of the present invention, the high-pressure gas consumption source is a turbine cogeneration system.

  According to the third characteristic configuration of the present invention, since the high-pressure gas consumption source is a turbine co-generation device, it is possible to generate power using fuel gas as in the conventional case, and it is necessary for the power generation. For example, when power of 2000 kW is generated, the power consumption of the hydraulic pump is about 7.5 kW, which is about 0.375%, and the self-power consumption can be greatly improved.

  According to a fourth aspect of the present invention, the high-pressure gas consumption source includes a pressure-reducing valve and a buffer tank that are depressurized and stored in a plurality of pressure sections, and the fuel gas is supplied to the gas consumption sources having different pressures. .

  According to the fourth characteristic configuration of the present invention, by providing a pressure reducing valve and a buffer tank for depressurizing and storing the pressure for supplying the fuel gas to the high pressure gas consumption source for each desired pressure, for example, the first pressure section Is a consumption source such as a natural gas vehicle or an emergency cardle, the second pressure section that supplies it by a pressure reducing valve and a buffer tank can be a turbine co-generation system, and further pressure reduction The third pressure segment supplied by the valve can be an intermediate or low pressure consumption source.

  According to a fifth characteristic configuration of the present invention, the high-pressure gas consumption source includes a heat exchanger, and exchanges heat with an evaporator that vaporizes the liquefied fuel gas into fuel gas and hot water, steam, or the like. .

  According to the fifth characteristic configuration of the present invention, the gas consumption source in the pressure section includes a heat exchanger. For example, hot water, steam, etc. are taken out from a turbine cogeneration system, and liquefied fuel gas is extracted. It is possible to exchange heat with the evaporator that vaporizes the fuel gas, and the self-consuming fuel can be greatly improved.

Embodiments of a fuel gas supply facility according to the present invention will be described with reference to the drawings. Components used in the conventional facility described above and components having the same action will be described with the same reference numerals. .
The fuel gas supply facility according to the present invention vaporizes liquefied natural gas (hereinafter referred to as LNG), which is an example of liquefied fuel gas, into natural gas, which is an example of fuel gas, and supplies the natural gas to a gas consumption source. As shown in FIG. 1, the LNG tank 1 for storing the LNG conveyed by the tank lorry TL is provided.

The LNG tank 1 is connected to a hydraulic pump 2 that pressurizes and pressurizes the LNG from the LNG tank 1 in a liquid state via a first transfer line L1 having a first valve V1. An evaporator 3 is connected to the pump 2 via a second transfer line L2 having a check valve type second valve V2.
The evaporator 3 is connected to a turbine cogeneration device 4 as an example of a high-pressure gas consumption source via a third transfer line L3 having a pressure reducing valve V5 and a buffer tank 16, and a fourth transfer line L4. A gas accumulator 7 for a natural gas vehicle 5 or an emergency cardle 6 which is an example of a high-pressure gas consumption source is connected via an evaporator, and the gas accumulator 7 and the turbine co-generation device 4 are connected to an evaporator. 3 are connected to each other in parallel.

The turbine-type cogeneration apparatus 4 includes a combustor 8 that combusts natural gas from the third transfer line L3, a turbine 9 that is rotationally driven by exhaust gas after combustion, an air compressor 10 that is linked to the turbine 9, and a generator. The air after being compressed by the air compressor 10 is heated by the exhaust gas in the heat exchanger 12, and then supplied to the combustor 8 as combustion air.
The gas accumulator 7 is for supplying the natural gas from the fourth transfer line L4 to the natural gas automobile 5 and the emergency cardle 6 as necessary, and before and after the third valve V3 and the fourth valve A valve V4 is provided.

The buffer tank 16 is connected to a boiler 15 which is an example of a medium pressure or low pressure gas consumption source or a general household gas appliance 17 through a fifth transfer line L5 having a pressure reducing valve V6. On the other hand, the natural gas from the third transfer line L3 is supplied after being reduced to a predetermined pressure by the pressure reducing valves V5 and V6.
The evaporator 3 receives supply of hot water, steam, and the like required to vaporize LNG into natural gas, and therefore, the evaporator 3 is connected to the heat exchanger 12 of the turbine-type cogeneration device 4 via the sixth transport line L6, and the seventh It is connected to the boiler 15 via the transport line L7.

Next, the operation of this fuel gas supply facility will be described.
First, the LNG transported by the tank lorry TL is stored in the LNG tank 1 under a pressure of 0.4 to 0.6 MPa and supplied to the hydraulic pump 2 at the same pressure through the first transport line L1. Then, the hydraulic pump 2 pressurizes the LNG as a liquid, raises the pressure to a required pressure of about 1.5 to 25 MPa, and supplies the pressure to the evaporator 3.

The evaporator 3 vaporizes the LNG into natural gas, and the natural gas after being vaporized is supplied to the combustor 8 of the turbine cogeneration device 4 at a pressure of about 1.5 to 2.0 MPa, which is necessary. Accordingly, when the gas is stored in the gas accumulator 7, the pressure is increased to about 20 to 25 MPa and supplied.
The combustor 8 is supplied with combustion air compressed by the air compressor 10 together with natural gas, and the exhaust gas after the combustion rotationally drives the turbine 9, and the air compressor 10 is driven along with the rotational drive of the turbine 9. The generator 11 is also rotationally driven, and is generated by the rotational drive of the generator 11.

For example, when the generator 11 generates 2000 kW of power, the power consumption of the hydraulic pump 2 required for the power generation is about 7.5 kW, and a self-power consumption of about 0.375% is sufficient.
The natural gas vehicle 5 and the emergency cardle 6 are supplied with high-pressure natural gas of about 20 MPa as necessary.

Another embodiment of the fuel gas supply facility according to the present invention will be described with reference to FIG.
In the other embodiment shown in FIG. 2, the detailed description of the components shown in FIG. 1 and the components having the same action is omitted by giving the same reference numerals, and the other embodiments shown in FIG. Now, the operation will be mainly described.

The vaporized natural gas leaving the evaporator 3 is stored in the gas accumulator 7 at a high pressure of about 20 to 25 MPa, which is necessary for the natural gas automobile 5 and the emergency card 6 which are high pressure gas consumption sources.
The gas accumulator 7 not only supplies natural gas to the natural gas vehicle 5 and emergency curdle 6 which are high pressure gas consumption sources, but also reduces the pressure to a different pressure by the pressure reducing valve V5, and serves as a turbine type co The pressure is reduced to about 1.5 to 2.0 MPa necessary for the generation device 4 and stored in the buffer tank 16.
The buffer tank 16 not only supplies natural gas to the turbine cogeneration system 4 that is a high-pressure gas consumption source, but also depressurizes to a different pressure by a pressure reducing valve V6, and is a boiler that is an example of a medium-pressure or low-pressure gas consumption source. 15 and gas appliances 17 for general households are supplied after being reduced to a necessary pressure.
Further, when the heat exchanger 12 is included in the fuel gas consumption source, the evaporator 3 is connected to the transport line L6 such as hot water or steam and used for heat exchange of the evaporator 3.

[Another embodiment]
In the previous embodiment, the turbine co-generation device 4 has been shown as an example of a high-pressure gas consumption source. However, the industrial co-generation device is not limited to a turbine co-generation device, and various industrial devices that require high-pressure fuel gas. It can also be applied.
Moreover, although liquefied natural gas was shown as an example of liquefied fuel gas, it is applicable also to various liquefied gases other than liquefied natural gas.

Schematic configuration diagram of fuel gas supply equipment according to the present invention Other schematic configuration diagram of fuel supply facility according to the present invention Schematic configuration diagram of conventional fuel supply equipment

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Tank 2 Hydraulic pump 3 Evaporator 4 Turbine-type cogeneration system as a high pressure gas consumption source 5 Natural gas vehicle as a high pressure gas consumption source 6 Emergency cardle as a high pressure gas consumption source 7 Gas storage 8 Combustor 9 Turbine 10 driven by combustion exhaust gas Air compressor 11 Generator 12 Heat exchanger 13 Auxiliary tank 14 Compressor 15 Boiler 16 as medium pressure or low pressure gas consumption source Buffer tank 17 Gas appliance TL as medium pressure or low pressure gas consumption source Tanker truck

Claims (5)

A tank for storing the liquefied fuel gas transported by the tank lorry and an evaporator for vaporizing the liquefied fuel gas into the fuel gas, and consuming the high-pressure gas from the fuel gas after the liquefied fuel gas from the tank is evaporated by the evaporator A fuel gas supply facility configured to supply a gas consumption source including a source,
A fuel gas supply facility comprising a hydraulic pump for pressurizing the liquefied fuel gas from the tank and supplying the liquefied fuel gas to the evaporator.   The said gas consumption source contains an intermediate pressure or a low pressure gas consumption source, The fuel gas after having vaporized by the said evaporator to the intermediate pressure or a low pressure gas consumption source is pressure-reduced and supplied. Fuel gas supply equipment.   The fuel gas supply facility according to claim 1 or 2, wherein the high-pressure gas consumption source is a turbine-type cogeneration device.   4. The fuel gas supply device according to claim 1, further comprising a pressure reducing valve and a buffer tank that decompress and store the high pressure gas consumption source in a plurality of pressure sections, and supply fuel gas to the gas consumption source having different pressures. Fuel gas supply equipment.   The fuel according to any one of claims 1 to 4, wherein the gas consumption source includes a heat exchanger, and heat exchange is performed using an evaporator that vaporizes the liquefied fuel gas into fuel gas and hot water, steam, or the like. Gas supply equipment.

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