JP2016148001A - Heat amount control system for liquefied gas shipping facility - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heat amount control system capable of suppressing a BOG (boil-off gas), generated after heat amount control, within an allowable range.SOLUTION: A heat amount control system for a liquefied gas shipping facility that transfers LNG stored in an LNG tank 1 installed in an LNG terminal to a transportation tank 3 mounted on a liquefied gas transportation device 2 and ships the LNG comprises: the LNG tank 1; an LNG supply line 4 that supplies LNG stored in the LNG tank 1; an LPG tank 5 that stores LPG used for heat amount control of the LNG; an LPG supply line 6 that supplies the LPG stored in the LPG tank 5; a cooling device 7 that cools the LPG in the middle of the LPG supply line 6 ; a mixing device 11 that mixes the liquid phase of the LNG supplied from the LNG supply line 4 with the liquid phase of the LPG supplied from the LPG supply line 6 and having being cooled by the cooling device 7; and a shipping line 14 that supplies the liquefied gas after heat amount control by the mixing device 11 to the transportation tank 3.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a quantity of heat for liquefied gas shipping equipment in which LNG stored in an LNG tank provided in an LNG (liquefied natural gas) base is filled in a transport tank mounted on a liquefied gas transport device and shipped. Regarding the adjustment system.

In Patent Document 1, LNG stored in an LNG tank provided at an LNG base is filled in a liquefied gas transport device such as an LNG carrier or a lorry vehicle and shipped. Shipping equipment is listed.
In the liquefied gas shipping facility described in Patent Document 1, the LNG stored in the LNG tank is shipped as it is, but it may be required to ship the LNG after adjusting the amount of heat.

Patent Document 2 describes a calorie adjusting device for city gas in which LNG having a low calorific value and LPG (liquefied petroleum gas) for increasing heat are mixed. Therefore, when the apparatus described in Patent Document 2 is used, a liquefied gas having a desired calorific value can be obtained.
In addition, the calorie | heat amount adjustment apparatus described in patent document 2 is equipped with the vaporizer | carburetor (6) which vaporizes the liquefied gas after performing calorie | heat amount adjustment, and is not shipping gas in the state liquefied. Absent.

JP 2011-093551 A JP 2000-192060 A

The liquefied gas obtained in the apparatus described in Patent Document 2 (that is, the liquefied gas obtained by mixing LNG with a low calorific value and LPG for increasing heat) is not vaporized and remains in a liquid state as described in Patent Document 1. In some cases, such a liquefied gas transport device is required to ship to an LNG satellite base.
However, the boiling point at normal pressure is much lower in LNG (about −160 ° C.) than in LPG (propane: about −42 ° C., butane: about −0.5 ° C.). Therefore, normally, LPG having a significantly higher temperature is mixed with LNG. Even in the apparatus described in Patent Document 2, it is considered that LPG for heat increase significantly higher than that is mixed with low heat quantity LNG. In this case, the temperature of LNG contained in the liquefied gas after mixing rises, and the amount of so-called BOG (boil-off gas) generated may increase.

  This invention is made | formed in view of said subject, The objective is to provide the calorie | heat amount adjustment system for liquefied gas shipping facilities which can suppress the generation | occurrence | production BOG after performing calorie | heat amount adjustment to a tolerance | permissible_range. .

The characteristic configuration of the liquefied gas shipping facility according to the present invention for achieving the above object is that the LNG stored in the LNG tank provided in the LNG base is transferred to the transport tank mounted on the liquefied gas transport device. A calorific value adjustment system for liquefied gas shipping equipment to be transported and shipped,
The LNG tank;
An LNG supply line for supplying LNG stored in the LNG tank;
An LPG tank for storing LPG used to adjust the amount of heat of LNG;
An LPG supply line for supplying LPG stored in the LPG tank;
A cooling device for cooling the LPG in the middle of the LPG supply line;
A mixing device for mixing the LNG supplied from the LNG supply line and the LPG supplied from the LPG supply line after being cooled by the cooling device in a liquid phase;
And a shipping line for supplying the liquefied gas after the calorific value is adjusted by the mixing device to the transport tank of the liquefied gas transport device.

  According to the above characteristic configuration, the LNG and the liquid phase are mixed with each other after the LPG is cooled by the cooling device. In other words, the temperature rise width of the LNG due to mixing is smaller than that in the case of mixing uncooled LPG. As a result, it is possible to ship a liquefied gas containing LNG whose calorific value is adjusted by LPG while reducing the amount of BOG generated.

Another characteristic configuration of the calorific value adjustment system for the liquefied gas shipping facility according to the present invention is communicated with the inside of the transport tank when the transport tank is filled with the liquefied gas from the shipping line, A gas extraction line for extracting gas phase components present in the transport tank;
A transportation pressure adjusting device which is provided in the middle of the gas extraction line and adjusts the pressure of the gas phase component extracted from the inside of the transportation tank.

  According to the above characteristic configuration, the pressure of the gas phase component extracted from the inside of the transport tank, that is, the pressure applied to the liquefied gas in the transport tank can be adjusted by the transport pressure adjusting device. As a result, even when the temperature of the liquefied gas in the transport tank becomes high, vaporization of the liquefied gas, that is, generation of BOG can be suppressed by keeping the pressure high by the transport pressure adjusting device.

  Still another characteristic configuration of the calorific value adjustment system for the liquefied gas shipping facility according to the present invention is that the cooling device circulates a turbo refrigerator, a Freon refrigerator that circulates a refrigerant containing a Freon gas, or a refrigerant that contains propylene. This is a propylene refrigerator.

  According to the above characteristic configuration, the LPG can be cooled using a refrigerator such as a turbo refrigerator, a Freon refrigerator, or a propylene refrigerator instead of a special device.

  Still another characteristic configuration of the calorific value adjustment system for liquefied gas shipping equipment according to the present invention is that the cooling device is a heat exchanger that exchanges heat between LNG as a refrigerant and LPG flowing through the LPG supply line. is there.

  According to the above characteristic configuration, since heat exchange between LPG and LNG is performed in the heat exchanger, the temperature of the cooled LPG can be brought close to the temperature of LNG. As a result, the amount of BOG generated when the cooled LPG and LNG are mixed can be reduced. For example, LNG as a refrigerant used for heat exchange with LPG can use LNG used for cold storage circulation at the LNG terminal, gas delivery LNG as a raw material for city gas production, and the like.

  Still another characteristic configuration of the calorific value adjustment system for liquefied gas shipping equipment according to the present invention is that an LPG storage tank for storing LPG after being cooled by the cooling device is provided in the middle of the LPG supply line.

The timing of shipping the liquefied gas with a liquefied gas transport device such as an LNG carrier or a lorry vehicle is irregular. Further, the required amount of liquefied gas shipped varies. Therefore, every time the liquefied gas is shipped by the liquefied gas transport device, cooling of the LPG in the cooling device and mixing of the LNG in the mixing device and the LPG after cooling will start and stop the cooling device, etc. Need to be performed each time. Further, in order to increase the shipment amount of liquefied gas per unit time to the liquefied gas transport device and to cope with various shipment timings, the cooling capacity per unit time of the LPG in the cooling device is increased. Necessary, that is, it is necessary to enlarge the cooling device.
However, according to the above-described characteristic configuration, the LPG after being cooled by the cooling device is stored in advance using the LPG storage tank, so that the liquefied gas is shipped at the liquefied gas transport device such as an LNG carrier or a lorry vehicle. There is no need to start and stop the cooling device. In addition, since the cooled LPG can be stored in the LPG storage tank, the cooling amount of LPG per unit time in the cooling device should be set to be equalized separately from the required shipment amount of liquefied gas Can do. In addition, since the cooled LPG can be stored in the LPG storage tank, the shipment amount per unit time of the liquefied gas to the liquefied gas transport device can be increased while reducing the size of the cooling device, and It is also possible to cope with various shipping timings.

  Still another characteristic configuration of the calorific value adjustment system for liquefied gas shipping equipment according to the present invention is that a storage tank pressure adjusting device for adjusting the pressure of the gas phase inside the LPG storage tank is provided.

  According to the above characteristic configuration, the pressure of the gas phase inside the LPG storage tank, that is, the pressure applied to the LPG in the LPG storage tank can be adjusted by the storage tank pressure adjusting device. As a result, the LPG in the LPG storage tank can be supercooled by the storage tank pressure adjusting device.

It is a figure which shows the structure of the calorie | heat amount adjustment system for liquefied gas shipment facilities of 1st Embodiment. It is a figure which shows the structure of the calorie | heat amount adjustment system for liquefied gas shipment facilities of 2nd Embodiment. It is a figure which shows the structure of the calorie | heat amount adjustment system for liquefied gas shipment facilities of 3rd Embodiment. It is a figure which shows the structure of the calorie | heat amount adjustment system for liquefied gas shipment facilities of 4th Embodiment.

<First Embodiment>
A heat quantity adjustment system for a liquefied gas shipping facility according to a first embodiment of the present invention will be described below with reference to the drawings.
FIG. 1 is a diagram illustrating a configuration of a calorific value adjustment system for a liquefied gas shipping facility according to the first embodiment. As shown in the figure, the calorific value adjustment system for liquefied gas shipping equipment includes an LNG tank 1, an LNG supply line 4, an LPG tank 5, an LPG supply line 6, a cooling device 7, a mixing device 11, and a shipping line. 14.

  An LNG tank 1 provided in an LNG base such as an LNG receiving base or an LNG shipping base stores LNG (liquefied natural gas) received from an LNG tanker or the like. Usually, a plurality of LNG tanks 1 are provided in the LNG base. The boiling point of LNG is about -160 ° C at normal pressure.

  The LNG supply line 4 supplies the LNG stored in the LNG tank 1 to the outside of the tank. In the LNG tank 1, an LNG pump 16 for pumping out LNG and sending it to the LNG supply line 4 is installed. The flow rate per unit time of LNG flowing through the LNG supply line 4 is adjusted by the LNG pump 16.

The LPG tank 5 stores LPG (liquefied petroleum gas) used for adjusting the amount of heat of LNG. LPG is mainly composed of propane or butane. In the case of propane, the boiling point at normal pressure is about -42 ° C. In the case of butane, the boiling point at normal pressure is about -0.5 ° C. The LPG supply line 6 supplies the LPG stored in the LPG tank 5 to the outside of the tank.
In the middle of the LPG supply line 6, an LPG pump 8 for adjusting the flow rate per unit time of the LPG is provided. A cooling device 7 described later is provided on the downstream side of the LPG pump 8.

In the middle of the LPG supply line 6 between the LPG pump 8 and the cooling device 7, a flow rate adjusting valve 9 for adjusting the flow rate of the LPG flowing through the LPG supply line 6 is provided. The flow rate of the LPG supplied to the cooling device 7 is adjusted by the action of the flow rate adjusting valve 9.
A flow rate adjusting valve 10 for adjusting the flow rate of the LPG flowing through the LPG supply line 6 is provided in the middle of the LPG supply line 6 between the cooling device 7 and the junction 12. The flow rate of the LPG supplied to the merging unit 12 is adjusted by the action of the flow rate adjusting valve 10.

  The cooling device 7 cools the LPG in the middle of the LPG supply line 6. For example, the cooling device 7 is a refrigerator such as a turbo refrigerator that uses a turbo compressor for refrigerant compression, a Freon refrigerator that circulates a refrigerant containing CFCs, or a propylene refrigerator that circulates a refrigerant containing propylene. It can be realized using. In the figure, the refrigerant that exchanges heat with the LPG is not shown. Further, the LPG may be cooled using an intermediate medium instead of directly cooling the LPG with the refrigerant of the refrigerator. For example, a configuration in which brine (ethylene glycol aqueous solution) as an intermediate medium is cooled by a refrigerator and the LPG is cooled by the cooled intermediate medium may be employed.

  The mixing device 11 mixes the LNG supplied from the LNG supply line 4 and the LPG supplied from the LPG supply line 6 after being cooled by the cooling device 7 in a liquid phase, and LNG and LPG are mixed. A liquefied gas containing is obtained. For example, in the present embodiment, the mixing device 11 merges the LNG supply line 4 and the LPG supply line 6 at the merge unit 12 and mixes the LNG and LPG merged at the merge unit 12 with the static mixer 13. In this case, the operation control of the LNG pump 16 and the flow control valve 10 is performed so that the mixing ratio of LPG to LNG becomes a desired value calculated in advance, that is, a liquefied gas having a desired heat amount is obtained. Is called. As described above, in the present embodiment, the LPG is cooled by the cooling device 7 and then mixed with the LNG and the liquid phase. In other words, the temperature rise width of the LNG due to mixing is smaller than that in the case of mixing uncooled LPG. As a result, it is possible to ship a liquefied gas mainly containing LNG whose calorific value has been adjusted by LPG while keeping the amount of BOG generated within an allowable range in consideration of equipment processing capacity and the like.

  The shipping line 14 supplies the liquefied gas (liquefied gas containing LNG and LPG) after the calorific value is adjusted by the mixing device 11 to the transport tank 3 of the liquefied gas transport device 2. An on-off valve 24 is provided in the middle of the shipping line 14. When the liquefied gas flows through the shipping line 14, the on-off valve 24 is opened. When the liquefied gas does not flow through the shipping line 14, the on-off valve 24 is closed.

  In addition, in this embodiment, the calorific value adjustment system for liquefied gas shipping equipment is communicated with the inside of the transport tank 3 when the liquefied gas is filled into the transport tank 3 from the shipping line 14 and is used for transport. A gas extraction line 15 for extracting a gas phase component existing inside the tank 3 and a transport pressure that is provided in the middle of the gas extraction line 15 and adjusts the pressure of the gas phase component extracted from the inside of the transport tank 3. And an adjusting device 17. The transport pressure adjusting device 17 can be realized by using a valve whose opening degree can be adjusted. As described above, the pressure of the gas phase component extracted from the inside of the transport tank 3, that is, the pressure applied to the liquefied gas in the transport tank 3 can be adjusted by the valve 17 as the transport pressure adjusting device. As a result, even when the temperature of the liquefied gas in the transport tank 3 becomes high, vaporization of the liquefied gas can be suppressed by keeping the pressure high by the valve 17.

Table 1 below is an example of operation when a turbo refrigerator is used as the cooling device 7, and shows examples of temperature, pressure, flow rate, and density at each of the parts A to G in FIG. The diameter of the gas extraction line 15 is 6B. In addition, an example using LPG containing 100% propane is shown.
As shown in Table 1, when a turbo refrigerator is used, LPG at the site C immediately before being mixed with LNG can be cooled to 10 ° C. And the temperature of the liquefied gas in the site | part D after mixing LNG and LPG with the mixing apparatus 11 is about -145 degreeC. Thus, the liquefied gas after heat amount adjustment by the mixing apparatus 11 can be maintained at a low temperature. Further, in this example in which a turbo refrigerator is used as the cooling device 7, the pressure of the gas phase component extracted from the inside of the transport tank 3 is relatively increased using the valve 17. For example, the amount of vaporized LNG can be reduced by adjusting the pressure of the gas phase component extracted from the inside of the transport tank 3 to about 0.2 MPaG. For example, in the part G, BOG is 0.26 (t / h).

Tables 2 and 3 below are operation examples when a Freon refrigerator or a propylene refrigerator is used as the cooling device 7, and the temperature, pressure, flow rate, and the like at each of the parts A to G in FIG. An example of density is shown. In any case, the diameter of the gas extraction line 15 is 10B.
As shown in Table 2 and Table 3, when a Freon refrigerator is used, LPG at the site C just before being mixed with LNG can be cooled to -55 ° C, and when a propylene refrigerator is used. Can cool the LPG at site C just before being mixed with LNG to −40 ° C.
And the temperature of the liquefied gas in the site | part D after mixing LPG and LNG with the mixing apparatus 11 will be -151 degreeC when using a Freon refrigerator, and will be about-when using a propylene refrigerator. 150 ° C. Thus, the liquefied gas after heat amount adjustment by the mixing apparatus 11 can be maintained at a low temperature. As a result, in the case of the Freon refrigerator (Table 2), the BOG is 0.85 (t / h) in the part G, and in the case of the propylene refrigerator (Table 3), in the part G. , BOG is 1.11 (t / h).

  As described above, when a Freon refrigerator or a propylene refrigerator is used as the cooling device 7, the temperature of the liquefied gas after the calorie adjustment is performed by the mixing device 11 is compared with the case where the turbo refrigerator is used. Is even lower. Therefore, when a Freon refrigerator or a propylene refrigerator is used as the cooling device 7, the pressure of the gas phase component extracted from the inside of the transport tank 3 using the valve 17 as the transport pressure adjusting device is set to the above-described turbo. You may make it lower than the case of a refrigerator. For example, even if the pressure of the gas phase component extracted from the inside of the transport tank 3 is adjusted to about 0.06 MPaG using the valve 17, the amount of LNG to be vaporized can be reduced. However, when the amount of LNG to be vaporized increases, it is preferable to increase the diameter of the gas extraction line 15 in advance to suppress the flow rate of the gas flowing in the pipe.

Second Embodiment
In the calorific value adjustment system for liquefied gas shipping equipment of the second embodiment, the configuration of the cooling device 7 is different from that of the first embodiment. Although the calorie | heat amount adjustment system for liquefied gas shipping facilities of 2nd Embodiment is demonstrated below, description is abbreviate | omitted about the structure similar to 1st Embodiment.

  FIG. 2 is a diagram illustrating a configuration of a calorific value adjustment system for a liquefied gas shipping facility according to the second embodiment. As shown in the figure, the cooling device 7 is configured using a heat exchanger 18 that exchanges heat between LNG as a refrigerant and LPG flowing through the LPG supply line 6. Specifically, the cooling device 7 employs a shell and tube heat exchanger. In the shell and tube heat exchanger 18, LNG is supplied to the tube side via the LNG line 19, and LPG is supplied to the shell side via the LPG supply line 6. In addition, the tube is a U tube so as to cope with the temperature change of LNG. For example, the LNG flowing through the LNG line 19 can be LNG used for cold storage and circulation at the LNG terminal, LNG for gas delivery as a raw material for city gas production, or the like.

Table 4 below is an operation example of the cooling device 7 using LNG as a refrigerant, and shows examples of temperature, pressure, flow rate, and density at each of the parts A to I in FIG. The diameter of the gas extraction line 15 is 6B. By adopting this configuration, the LPG at the site C just before being mixed with LNG can be cooled to -110 ° C. Thus, since heat exchange between the LPG and the LNG is performed in the heat exchanger 18, the temperature of the cooled LPG can be brought close to the temperature of the LNG. As a result, the amount of BOG generated when the cooled LPG and LNG are mixed can be reduced. In particular, in this example shown in Table 4, the amount of BOG generated in the gas extraction line 15 (part F, part G) is zero.
The temperature of the LNG after being used for cooling the LPG in the heat exchanger 18 rises. For example, the LNG can be supplied to a vaporizer or the like and vaporized to be used for generating city gas. Alternatively, the generated BOG may be sent to a BOG compressor to perform a process such as reliquefaction.

<Third Embodiment>
The calorie | heat amount adjustment system for liquefied gas shipping facilities of 3rd Embodiment differs from the said embodiment by the point provided with the storage tank which can store LPG temporarily. Although the structure of the calorie | heat amount adjustment system for liquefied gas shipping facilities of 3rd Embodiment is demonstrated below, description is abbreviate | omitted about the structure similar to the said embodiment.

  FIG. 3 is a diagram illustrating a configuration of a calorific value adjustment system for a liquefied gas shipping facility according to a third embodiment. As shown in the figure, the calorific value adjustment system for liquefied gas shipping equipment of this embodiment includes an LPG storage tank 20 that stores LPG after being cooled by the cooling device 7 in the middle of the LPG supply line 6. The LPG storage tank 20 can use equipment generally called a cold evaporator (CE). An LPG pump 21 for adjusting the flow rate per unit time of LPG is provided in the middle of the LPG supply line 6 between the LPG storage tank 20 and the junction 12. By the action of the LPG pump 21, the flow rate of LPG supplied from the LPG storage tank 20 to the merging section 12 is adjusted. Although FIG. 3 shows the case where the heat exchanger 18 described in the second embodiment is used as the cooling device 7, the refrigerator described in the first embodiment may be used as the cooling device 7. .

Usually, the timing at which liquefied gas is shipped by the liquefied gas transport device 2 such as an LNG carrier or a lorry vehicle is irregular. Further, the required amount of liquefied gas shipped varies. Therefore, whenever the liquefied gas is shipped by the liquefied gas transport device 2, the cooling of the LPG in the cooling device 7 and the mixing of the LNG and the cooled LPG in the mixing device 11 are performed. It is necessary to start (cool down operation) and stop each time.
However, in the present embodiment, the LPG storage tank 20 is used to store the LPG that has been cooled by the cooling device 7 in advance, so that the liquefied gas is shipped by the liquefied gas transport device 2 such as an LNG carrier or a lorry vehicle. There is no need to start and stop the cooling device 7 at the timing. In addition, since the cooled LPG can be stored in the LPG storage tank 20, the cooling amount of the LPG per unit time in the cooling device 7 is set to be equalized separately from the required shipment amount of the liquefied gas. can do. For example, the cooling device 7 can be operated such that LPG having a constant flow rate is continuously cooled and stored in the LPG storage tank 20.
Further, when the heat exchanger 18 described in the second embodiment is used as the cooling device 7, the heat exchanger 18 continuously exchanges heat between the constant flow rate LPG and the constant flow rate LNG. Therefore, the amount of BOG generated in the LNG line 19 is also substantially constant over time. Therefore, it becomes easy to use BOG.

  Although not shown, the LPG storage tank 20 is preferably equipped with a pressurized evaporator. This pressure evaporator evaporates the LPG taken out from the inside of the LPG storage tank 20 by, for example, heat exchange with the outside air and then sends it to the upper part of the LPG storage tank 20 so that the pressure in the LPG storage tank 20 becomes a desired pressure. Available to maintain.

  Table 5 below is an example of operation of the cooling device 7 using LNG as a refrigerant, and shows examples of temperature, pressure, flow rate, and density at each of the parts A to J in FIG. The diameter of the gas extraction line 15 is 10B. By adopting this configuration, the LPG at the site C just before being mixed with LNG can be cooled to about −39 ° C. As a result, the amount of LNG to be vaporized out of the LNG contained in the liquefied gas after mixing can be reduced. Moreover, the low-temperature LPG after being cooled by the cooling device 7 can be stored in the LPG storage tank 20 in advance.

<Fourth embodiment>
The calorie | heat amount adjustment system for liquefied gas shipment facilities of 4th Embodiment differs from the said 3rd Embodiment by the point provided with the storage tank pressure adjustment apparatus. Although the structure of the calorie | heat amount adjustment system for liquefied gas shipping facilities of 4th Embodiment is demonstrated below, description is abbreviate | omitted about the structure similar to the said 3rd Embodiment.

  FIG. 4 is a diagram illustrating a configuration of a calorific value adjustment system for a liquefied gas shipping facility according to a fourth embodiment. As shown in the drawing, the calorific value adjustment system for liquefied gas shipping equipment of the present embodiment includes a storage tank pressure adjusting device that adjusts the pressure of the gas phase inside the LPG storage tank 20. This storage tank pressure adjusting device has an inert gas supply line 22 for supplying an inert gas, and a pressure adjusting valve 23 for adjusting the flow rate of the inert gas flowing through the inert gas supply line 22. Although not shown, the inert gas supply line 22 is connected to an inert gas supply source that stores the inert gas. The storage tank pressure adjusting devices 22 and 23 supply an inert gas to the inside of the LPG storage tank 20 in order to adjust the pressure of the gas phase portion inside the LPG storage tank 20. By these storage tank pressure adjusting devices 22, 23, negative pressure in the gas phase portion inside the LPG storage tank 20 can be prevented. Although FIG. 4 shows the case where the heat exchanger 18 described in the second embodiment is used as the cooling device 7, the refrigerator described in the first embodiment may be used as the cooling device 7. .

  Table 6 below is an example of the operation of the cooling device 7 using LNG as a refrigerant, and shows examples of temperature, pressure, flow rate, and density at each of the parts A to J in FIG. The diameter of the gas extraction line 15 is 6B. By adopting this configuration, the LPG at the site C just before being mixed with LNG can be cooled to -110 ° C. As a result, the amount of LNG to be vaporized out of the LNG contained in the liquefied gas after mixing can be reduced. In particular, in this example shown in Table 6, the amount of BOG generated in the gas extraction line 15 (part F, part G) is zero.

  Moreover, the low-temperature LPG after being cooled by the cooling device 7 can be stored in the LPG storage tank 20 in advance. Furthermore, the LPG inside the LPG tank 20 can be supercooled by adjusting the pressure of the gas phase component inside the LPG tank 20 by the tank pressure adjusting devices 22 and 23. The pressure in the gas phase portion of the LPG storage tank 20 is maintained at about 0.1 MPaG with an inert gas (for example, nitrogen). As described above, the pressure of the gas phase component inside the LPG storage tank 20, that is, the pressure applied to the LPG in the LPG storage tank 20 can be adjusted by the storage tank pressure adjusting devices 22 and 23. As a result, it becomes possible to supercool the LPG in the LPG storage tank 20 by the storage tank pressure adjusting devices 22 and 23.

<Another embodiment>
In the said embodiment, although the specific example was given and demonstrated about the structure of the calorie | heat amount adjustment system for liquefied gas shipment facilities, the structure can be changed suitably.
For example, an LPG return pipe that returns LPG from the middle of the LPG supply line 6 to the LPG tank 5 may be provided. In particular, when the LPG return pipe is provided on the downstream side of the cooling device 7 in the middle of the LPG supply line 6, the entire amount of LPG cooled by the cooling device 7 can be returned to the LPG tank 5 again. It can be used at the time of start-up when the performance of is not fully demonstrated. Further, when the LPG return pipe is provided on the upstream side of the cooling device 7 in the middle of the LPG supply line 6, a part of the LPG sent from the LPG pump 8 is passed through the LPG return pipe and returned to the LPG tank 5. The remainder can be supplied to the cooling device 7. Therefore, the flow rate of LPG cooled by the cooling device 7 can be reduced.
In addition, in the said embodiment, although the specific numerical value was mentioned in Table 1-Table 6, they are described for the purpose of illustration.

  INDUSTRIAL APPLICABILITY The present invention can be used for a calorific value adjustment system for liquefied gas shipping equipment that can suppress the generated BOG after the calorific value adjustment to an allowable range.

DESCRIPTION OF SYMBOLS 1 LNG tank 2 Liquefied gas transport device 3 Transport tank 4 LNG supply line 5 LPG tank 6 LPG supply line 7 Cooling device 8 LPG pump 9 Flow rate control valve 10 Flow rate control valve 11 Mixing device 12 Junction part 13 Mixer 14 Shipping line 15 Gas extraction line 16 LNG pump 17 Valve (Transport pressure regulator)
18 Heat exchanger 19 LNG line 20 LPG storage tank 21 LPG pump 22 Inert gas supply line (storage tank pressure control device)
23 Pressure control valve (storage tank pressure control device)

Claims (6)

A calorific value adjustment system for a liquefied gas shipping facility in which LNG stored in an LNG tank provided at an LNG base is transported to a transport tank mounted on a liquefied gas transport device and shipped.
The LNG tank;
An LNG supply line for supplying LNG stored in the LNG tank;
An LPG tank for storing LPG used to adjust the amount of heat of LNG;
An LPG supply line for supplying LPG stored in the LPG tank;
A cooling device for cooling the LPG in the middle of the LPG supply line;
A mixing device for mixing the LNG supplied from the LNG supply line and the LPG supplied from the LPG supply line after being cooled by the cooling device in a liquid phase;
A calorific value adjustment system for a liquefied gas shipping facility, comprising: a shipping line that supplies the liquefied gas after the calorific value is adjusted by the mixing device to the transport tank of the liquefied gas transport device. A gas extraction line connected to the inside of the transportation tank when the transportation tank is filled with liquefied gas from the shipping line, and for extracting a gas phase component existing inside the transportation tank;
The calorific value adjustment system for a liquefied gas shipping facility according to claim 1, further comprising a transport pressure adjusting device that is provided in the middle of the gas extraction line and adjusts the pressure of a gas phase component extracted from the inside of the transport tank. .   The calorific value for the liquefied gas shipping facility according to claim 1 or 2, wherein the cooling device is a turbo refrigerator, a Freon refrigerator that circulates a refrigerant containing a Freon gas, or a propylene refrigerator that circulates a refrigerant containing propylene. Adjustment system.   The calorific value adjustment system for liquefied gas shipping equipment according to claim 1 or 2, wherein the cooling device is a heat exchanger that exchanges heat between LNG as a refrigerant and LPG flowing through the LPG supply line.   The calorific value adjustment system for liquefied gas shipping equipment according to any one of claims 1 to 4, further comprising an LPG storage tank for storing LPG after being cooled by the cooling device in the middle of the LPG supply line.   The calorie | heat amount adjustment system for liquefied gas shipping facilities of Claim 5 provided with the storage tank pressure adjustment apparatus which adjusts the pressure of the gaseous-phase part inside the said LPG storage tank.

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