JP4823338B2 - LNG satellite equipment - Google Patents

Description

  The present invention relates to a satellite facility for vaporizing LNG. In particular, the present invention relates to equipment for heating an LNG vaporizer in LNG satellite equipment.

  If the demand area such as a factory or a common facility that uses natural gas (hereinafter also referred to as NG) is far from the primary receiving base that accepts liquefied natural gas (hereinafter also referred to as LNG), it is close to the demand area A secondary receiving base (satellite base) is arranged in the base station, and natural gas is supplied from this satellite base to the demand area. In such a satellite base, an LNG vaporizer that vaporizes LNG is usually installed together with an LNG storage tank that stores LNG, and the LNG stored in the LNG storage tank is vaporized by the LNG vaporizer and is thus natural gas. And supplied to the demand area. This satellite base must always supply natural gas stably to the demand area.

  An LNG vaporizer installed in an LNG satellite facility uses, for example, warm water to heat and vaporize LNG. Therefore, in the LNG satellite facility, a hot water buffer tank that stores hot water for supplying hot water to the LNG vaporizer is used.

  For example, Patent Document 1 describes the use of a hot water tank for storing hot water. In Patent Document 1, a hot water generator is provided at the lower part of the hot water tank for storing hot water, hot water having a relatively small temperature difference is stored from the lower part to the upper part of the hot water tank, and the hot water is used from the upper part of the hot water tank. A method of supplying to a part is disclosed.

  However, in the method disclosed in Patent Document 1, since hot water is supplied from one hot water tank to the use part, if a foreign substance enters the tank and the supply part of the hot water is clogged, the use part is used. The hot water supply will stop. Once the supply of hot water is stopped, even if the hot water supply is resumed, the temperature of the hot water and the temperature of the hot water supply using part are not immediately recovered, and a great deal of damage is caused.

Japanese Patent Laid-Open No. 11-82912

  Therefore, an object of this invention is to provide the LNG satellite installation which can supply a hot water to a use part stably.

  The present invention is an LNG satellite facility for vaporizing LNG, an LNG storage tank in which LNG is stored, an LNG vaporizer that vaporizes LNG and generates gas, and warms the LNG vaporizer A first hot water buffer tank and a second hot water buffer tank for storing hot water supplied for the purpose, a first discharge nozzle portion provided at a lower portion of the first hot water buffer tank, and for discharging the hot water; A second discharge nozzle portion that is provided at a lower portion of the second hot water buffer tank and discharges hot water; hot water discharged from the first hot water buffer tank through the first discharge nozzle portion; and the second hot water A hot water supply pipe for supplying hot water discharged from the buffer tank through the second discharge nozzle portion to the LNG vaporizer, and water pressure of the first hot water buffer tank A first detection unit for detecting, a second detection unit for detecting a water pressure in the second hot water buffer tank, a notification unit for reporting an abnormality in a flow of hot water supplied to the LNG vaporizer, and the first When the difference between the value of the first water pressure detected from the first detection unit and the value of the second water pressure detected from the second detection unit is equal to or greater than a predetermined value, the abnormality is notified to the notification unit. And an LNG satellite facility including the control device.

  According to the LNG satellite facility of the present invention, the first detection unit that detects the water pressure of the first hot water buffer tank and the second detection unit that detects the water pressure of the second hot water buffer tank are provided. When the difference between the first water pressure value detected from the first detection unit and the second water pressure value detected from the second detection unit is equal to or greater than a predetermined value, the notification unit is notified of the abnormality. Thereby, when either one of the first warm water buffer tank or the second warm water buffer tank is clogged, an abnormality is notified. Therefore, even when an abnormality occurs in one of the hot water buffer tanks, the other hot water buffer tank is operated normally, so that the supply of hot water does not stop. As a result, warm water can be stably supplied to the warm water use section.

  In addition, the LNG satellite facility is attached to the first discharge nozzle unit and is attached to the first strainer and the second discharge nozzle unit. The first strainer is arranged to protrude inward of the first hot water buffer tank. It is preferable to further include a second strainer arranged to protrude inward of the second hot water buffer tank.

  According to the present invention, the first strainer attached to the first discharge nozzle portion and arranged to protrude inward of the first hot water buffer tank, and the second hot water buffer attached to the second discharge nozzle portion. And a second strainer that protrudes inward of the tank. Thereby, it is possible to prevent the foreign matter in the warm water in the first warm water buffer tank from entering the first discharge nozzle portion, and the foreign matter in the warm water in the second warm water buffer tank enters the second discharge nozzle portion. Prevent entry. Accordingly, clogging of foreign matters in the dispensing nozzle portion can be reduced.

  Each of the first strainer and the second strainer has a cylindrical shape, and it is preferable that a mesh member is disposed on the circumferential surface of the cylindrical shape.

  According to this invention, each of the 1st strainer and the 2nd strainer was made into the cylindrical shape, and the mesh-shaped member was arrange | positioned to the surrounding surface of this cylindrical shape. As a result, the suction area of the hot water discharged from each of the first discharge nozzle part and the second discharge nozzle part increases, thereby reducing the flow velocity and reducing the suction of foreign matter. Moreover, it is possible to prevent fine foreign matter from entering the first discharge nozzle portion and the second discharge nozzle portion due to the mesh shape. Accordingly, it is possible to further reduce clogging of foreign matters in the dispensing nozzle portion.

  According to the present invention, the first detection unit that detects the water pressure of the first hot water buffer tank and the second detection unit that detects the water pressure of the second hot water buffer tank are provided. When the difference between the detected first water pressure value and the second water pressure value detected from the second detection unit is equal to or greater than a predetermined value, the notification unit is notified of the abnormality. Thereby, when either one of the first warm water buffer tank or the second warm water buffer tank is clogged, an abnormality is notified. Therefore, even when an abnormality occurs in one of the hot water buffer tanks, the other hot water buffer tank is operated normally, so that the supply of hot water does not stop. As a result, warm water can be stably supplied to the warm water use section.

It is a schematic diagram which shows the LNG satellite installation of one Embodiment of this invention. It is a side view of the 1st strainer and the 2nd strainer of one embodiment of the present invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a schematic diagram showing an embodiment of the LNG satellite facility 100 of the present invention. FIG. 2 is a view showing the side surfaces of the first strainer 23 and the second strainer 24. The LNG satellite facility 100 is installed for the purpose of supplying natural gas to demand areas such as factories and shared facilities.

  As shown in FIG. 1, the LNG satellite facility 100 includes an LNG storage tank 1, an LNG vaporizer 2, a first hot water buffer tank 3, a second hot water buffer tank 4, and a first discharge nozzle unit 5. A second discharge nozzle unit 6, a hot water supply pipe 7, a first detection unit 8, a second detection unit 9, a notification unit 10, an LNG satellite facility control device 11 as a control device, LNG supply pipe 12, NG supply pipe 13, hot water generation section 14, hot water supply pipe 15, steam generation section 16, steam supply pipe 17, pump 18, hot water return pipes 19, 21, 22, A hot water return pipe control valve 20, a first strainer 23, a second strainer 24, an LNG flow pipe 25, and a hot water flow pipe 26 are provided.

  The LNG storage tank 1 stores LNG transported by an LNG lorry vehicle (not shown).

  The 1st warm water buffer tank 3 stores warm water used in order to vaporize LNG to NG.

  The second hot water buffer tank 4 stores hot water used for vaporizing LNG into NG.

  The hot water generator 14 generates hot water to be supplied to each of the first hot water buffer tank 3 and the second hot water buffer tank 4. The warm water generation unit 14 is configured by, for example, a boiler (not shown).

  The hot water supply pipe 15 connects the hot water generation unit 14 with the first hot water buffer tank 3 and the second hot water buffer tank 4. The downstream side of the hot water supply pipe 15 is branched into a hot water supply pipe 27a and a hot water supply pipe 27b. The hot water supply pipe 27a is connected to the first hot water buffer tank 3, and the hot water supply pipe 27b is connected to the second water supply pipe 27b. It connects with the warm water buffer tank 4. The upstream side of the hot water pipe 15 is connected to the hot water generator 14. The hot water supply pipe 15 supplies the warm water in the warm water generation unit 14 to the first warm water buffer tank 3 and the second warm water buffer tank 4.

  The steam generation unit 16 generates steam to be supplied to each of the first hot water buffer tank 3 and the second hot water buffer tank 4. The steam generation unit 16 is configured by, for example, a boiler (not shown). The steam generated by the steam generator 16 warms the hot water in the first hot water buffer tank 3 and the second hot water buffer tank 4. A steam supply valve (not shown) that adjusts the amount of steam supplied to the first hot water buffer tank 3 and the second hot water buffer tank 4 is provided in the steam generation unit 16.

  The steam supply pipe 17 connects the steam generation unit 16 to the first hot water buffer tank 3 and the second hot water buffer tank 4. The downstream side of the steam supply pipe 17 is branched into a steam supply pipe 29a and a steam supply pipe 29b, the steam supply pipe 29a is connected to the first hot water buffer tank 3, and the steam supply pipe 29b is connected to the second It connects with the warm water buffer tank 4. The upstream side of the steam supply pipe 17 is connected to the steam generation unit 16. The steam supply pipe 17 supplies the steam in the steam generator 16 to the first hot water buffer tank 3 and the second hot water buffer tank 4.

  The first discharge nozzle unit 5 discharges the hot water in the first hot water buffer tank 3. The first discharge nozzle unit 5 is provided in the lower part of the first hot water buffer tank 3.

  The second discharge nozzle unit 6 discharges the hot water in the second hot water buffer tank 4. The second discharge nozzle unit 6 is provided in the lower part of the second hot water buffer tank 4.

  The hot water supply pipe 7 connects the first discharge nozzle unit 5 and the second discharge nozzle unit 6 to the LNG vaporizer 2. The hot water supply pipe 7 is discharged from the first hot water buffer tank 3 through the first discharge nozzle portion 5 and from the second hot water buffer tank 4 through the second discharge nozzle portion 6. Hot water is supplied to the LNG vaporizer 2. The upstream side of the hot water supply pipe 7 branches into a pipe connected to the first discharge nozzle part 5 and a pipe connected to the second discharge nozzle part 6. The pipe connected to the first discharge nozzle unit 5 is provided with a hot water supply pipe adjustment valve 7 a for adjusting the amount of hot water supplied from the first hot water buffer tank 3, and connected to the second discharge nozzle unit 6. The pipe to be provided is provided with a hot water supply pipe adjustment valve 7b for adjusting the amount of hot water supplied from the second hot water buffer tank 4. The downstream side of the hot water supply pipe 7 branches into a hot water supply pipe 7c connected to the LNG vaporizer 2 and a bypass pipe 7d.

  The downstream end of the bypass pipe 7 d is connected to the hot water return pipe 19. The bypass pipe 7d is provided with a bypass pipe adjustment valve 31 that adjusts the amount of hot water flowing through the bypass pipe 7d. The bypass pipe 7 d sends a part of the hot water flowing through the hot water supply pipe 7 to the hot water return pipe 19. The hot water supply pipe 7 is provided with a temperature sensor (not shown) that measures the temperature of the hot water supplied to the LNG vaporizer 2.

  The pump 18 is provided in the hot water supply pipe 7. The pump 18 supplies the hot water stored in the first hot water buffer tank 3 and the second hot water buffer tank 4 to the LNG vaporizer 2 via the hot water supply pipe 7.

  The LNG vaporizer 2 converts LNG into NG using the hot water supplied from the first hot water buffer tank 3 and the second hot water buffer tank 4. The LNG vaporizer 2 includes hot water supplied from the LNG flow pipe 25 through which the LNG supplied from the LNG storage tank 1 (NG after conversion) flows, and the first hot water buffer tank 3 and the second hot water buffer tank 4. Is provided with a hot water circulation pipe 26.

  The upstream side of the LNG circulation pipe 25 is connected to the LNG supply pipe 12 that supplies the LNG in the LNG storage tank 1 to the LNG vaporizer 2. The downstream side of the LNG flow pipe 25 is connected to the NG supply pipe 13. In the LNG distribution pipe 25, LNG supplied via the LNG supply pipe 12 is converted to NG. The converted NG flows through the LNG distribution pipe 25 and is supplied to the NG supply pipe 13.

  The NG supply pipe 13 supplies the vaporized NG to the demand area. A temperature sensor 30 is provided on the LNG flow pipe 25 side of the NG supply pipe 13 (an outlet of the LNG vaporizer 2). The temperature sensor 30 provided in the NG supply pipe 13 measures the temperature of the converted NG.

  The hot water circulation pipe 26 is connected to the hot water supply pipe 7 c on the upstream side and to the hot water return pipe 19 on the downstream side. The hot water in the hot water flow pipe 26 supplied from the hot water supply pipe 7c heats the LNG in the LNG flow pipe 25, and LNG is converted to NG. The warm water in the warm water circulation pipe 26 circulates in the warm water circulation pipe 26 and is supplied to the warm water return pipe 19.

  The upstream side of the warm water return pipe 19 is connected to the warm water circulation pipe 26. The downstream side of the hot water return pipe 19 is connected to the hot water return pipe 21 and the hot water return pipe 22. The hot water return pipe 19 sends the hot water supplied from the hot water circulation pipe 26 and the bypass pipe 7 d to the hot water return pipe 21 or the hot water return pipe 22.

  The warm water return pipe 21 is branched downstream into a warm water return pipe 28a and a warm water return pipe 28b. The warm water return pipe 28a is connected to the first warm water buffer tank 3, and the warm water return pipe 28b is connected to the second water return pipe 28b. Connected to the hot water buffer tank 4. The hot water return pipe 21 returns the hot water sent via the hot water return pipe 19 to the first hot water buffer tank 3 and the second hot water buffer tank 4. The warm water returned to the first warm water buffer tank 3 and the second warm water buffer tank 4 is stored to be supplied to the LNG vaporizer 2 again.

  The hot water return pipe 22 is connected to the hot water generator 14 at the downstream side. The warm water return pipe 22 is provided with a warm water return pipe 21 and a warm water return pipe control valve 20 that adjusts the amount of warm water flowing through the warm water return pipe 22. The hot water return pipe 22 returns the hot water sent via the hot water return pipe 19 to the hot water generator 14. The warm water returned to the warm water generator 14 is heated again.

  The first detection unit 8 is provided in the first hot water buffer tank 3. The first detection unit 8 detects the water pressure in the first hot water buffer tank 3. The 1st detection part 8 is comprised by the sensor which detects a water pressure, for example.

  The second detection unit 9 is provided in the second hot water buffer tank 4. The second detection unit 9 detects the water pressure in the second hot water buffer tank 4. The 2nd detection part 9 is comprised by the sensor which detects a water pressure, for example.

  The alerting | reporting part 10 alert | reports abnormality, when abnormality of the warm water supplied to the LNG vaporizer 2 arises. Moreover, the alerting | reporting part 10 alert | reports abnormality, when the temperature of NG which distribute | circulates the NG supply pipe | tube 13 becomes below a predetermined value. The alerting | reporting part 10 is comprised by the alarm device for alerting | reporting abnormality, for example.

  The LNG satellite facility control device 11 includes an abnormality notification control device 111, a bypass pipe control valve control device 112, a hot water return pipe control valve control device 113, and a hot water buffer tank temperature control device 114.

  The abnormality notification control device 111 causes the notification unit 10 to notify the abnormality of the LNG satellite facility 100. Specifically, the abnormality notification control device 111 has a predetermined difference between the first water pressure value detected by the first detection unit 8 and the second water pressure value detected by the second detection unit 9. When it becomes more than the value, the notification unit 10 is notified of the abnormality. In addition, the abnormality notification control device 111 causes the notification unit 10 to notify the abnormality when the temperature of the NG measured by the temperature sensor 30 provided in the NG supply pipe 13 becomes a predetermined value or less.

  The bypass pipe control valve control device 112 controls the open / close state of the bypass pipe control valve 31 according to the temperature sensor 30 provided in the NG supply pipe 13. Specifically, when the temperature of the NG measured by the temperature sensor 30 is equal to or higher than a predetermined value, the bypass pipe control valve control device 112 increases the opening of the bypass pipe control valve 31, and the temperature of the NG is a predetermined value. In the following cases, the opening degree of the bypass pipe control valve 31 is reduced.

  The hot water return pipe control valve control device 113 adjusts the hot water return pipe according to the first water pressure value detected by the first detection unit 8 and the second water pressure value detected by the second detection unit 9. The open / close state of the valve 20 is controlled. Specifically, the hot water return pipe control valve control device 113 reduces the opening of the hot water return pipe control valve 20 when the first water pressure value and the second water pressure value are less than or equal to a predetermined value, When the value of the water pressure exceeds a predetermined value, the opening degree of the hot water return pipe control valve 20 is increased.

  The hot water buffer tank temperature control device 114 controls the open / close state of the steam supply valve provided in the steam generation unit 16 according to the temperature sensor provided in the hot water supply pipe 7. Specifically, the warm water buffer tank temperature control device 114 increases the opening of the steam supply valve when the temperature of the warm water measured by the temperature sensor provided in the warm water supply pipe 7 becomes a predetermined value or less. When the temperature of the hot water exceeds a predetermined value, the opening of the steam supply valve is reduced.

  The first strainer 23 includes a cylindrical strainer body and a mesh member disposed on the inner surface side of the body. The first strainer 23 is attached to the first discharge nozzle portion 5 and is disposed so as to protrude inward of the first hot water buffer tank 3. One end of the first strainer 23 is connected to the first dispensing nozzle unit 5. The other end of the first strainer 23 is closed. The first strainer 23 has a plurality of openings on the peripheral surface, and a mesh member is provided in the opening from the inner surface side. The warm water in the first warm water buffer tank 3 is discharged to the first discharge nozzle portion 5 through the mesh member of the opening.

  The second strainer 24 includes a cylindrical strainer body and a mesh member disposed on the inner surface side of the body. The second strainer 24 is attached to the second discharge nozzle portion 6 and is disposed so as to protrude inward of the second hot water buffer tank 4. One end of the second strainer 24 is connected to the second dispensing nozzle unit 6. The other end of the second strainer 24 is closed. The second strainer 24 has a plurality of openings on the peripheral surface, and a mesh member is provided in the opening from the inner surface side. The hot water in the second hot water buffer tank 4 is discharged to the second discharge nozzle portion 6 through the mesh member of the opening.

  According to the satellite facility 100 described above, the following effects can be obtained.

  A first detection unit 8 that detects the water pressure of the first hot water buffer tank 3 and a second detection unit 9 that detects the water pressure of the second hot water buffer tank 4 are provided and detected from the first detection unit 8. When the difference between the first water pressure value and the second water pressure value detected by the second detection unit 9 is equal to or greater than a predetermined value, the notification unit 10 is notified of the abnormality. As a result, an abnormality is notified when either the first hot water buffer tank 3 or the second hot water buffer tank 4 is clogged. Therefore, even when an abnormality occurs in one of the hot water buffer tanks, the other hot water buffer tank is operated normally, so that the supply of hot water does not stop. As a result, warm water can be stably supplied to the warm water use section.

  A first strainer 23 attached to the first discharge nozzle unit 5 and arranged to protrude inward of the first hot water buffer tank 3, and a second hot water buffer tank 4 attached to the second discharge nozzle unit 6. And a second strainer 24 that protrudes inwardly. Thereby, it is possible to prevent the foreign matter in the warm water in the first warm water buffer tank 3 from entering the first dispensing nozzle unit 5, and the foreign matter in the warm water in the second warm water buffer tank 4 is the second dispensing. It is possible to prevent the nozzle unit 6 from entering. Accordingly, clogging of foreign matters in the dispensing nozzle portion can be reduced.

  Each of the 1st strainer 23 and the 2nd strainer 24 was made into the cylindrical shape, and the mesh-shaped member was arrange | positioned on the surrounding surface of this cylindrical shape. As a result, the suction area of the hot water discharged from each of the first discharge nozzle portion 5 and the second discharge nozzle portion 6 increases, thereby reducing the flow velocity and reducing the suction of foreign matter. Moreover, it is possible to prevent fine foreign matter from entering the first discharge nozzle portion 5 and the second discharge nozzle portion 6 due to the mesh shape. Accordingly, it is possible to further reduce clogging of foreign matters in the dispensing nozzle portion.

  When the bypass pipe control valve 31 and the bypass pipe control valve control device 112 are provided and the temperature of the NG measured by the temperature sensor 30 provided in the NG supply pipe 13 becomes a predetermined value or less, the bypass pipe control valve 31 The opening of the bypass pipe control valve 31 was increased when the temperature of the NG became a predetermined value or higher. Thereby, when the temperature of NG measured with the temperature sensor 30 becomes below a predetermined value, the quantity of the hot water supplied to the LNG vaporizer 2 can be increased, and the temperature of the LNG vaporizer 2 can be raised. When the temperature of the NG becomes a predetermined value or more, the amount of hot water supplied to the LNG vaporizer 2 can be reduced, and the temperature of the LNG vaporizer 2 can be lowered. Therefore, the temperature of NG converted in the LNG vaporizer 2 can be kept constant.

  The hot water return pipe control valve 20 and the hot water return pipe control valve control device 113 are provided, and the first water pressure value detected from the first detection unit 8 and the second water pressure detected from the second detection unit 9 are provided. When the water pressure value is less than or equal to the predetermined value, the opening degree of the hot water return pipe control valve 20 is decreased. When the water pressure value is greater than or equal to the predetermined value, the opening degree of the hot water return pipe control valve 20 is decreased. Made it bigger. Thereby, when the water pressure in the 1st warm water buffer tank 3 and the 2nd warm water buffer tank 4 becomes below a predetermined value, the quantity of warm water which flows into warm water return pipe 21 is increased, and 1st warm water buffer tank 3 and The warm water can be returned to the second warm water buffer tank 4 again. When the water pressure in the 1st warm water buffer tank 3 and the 2nd warm water buffer tank 4 becomes more than a predetermined value, the quantity of warm water which flows into warm water return pipe 21 is decreased, and warm water is generated warm water via warm water return pipe 22 It can be returned to the part 14. Therefore, the hot water circulating in the LNG satellite facility can be efficiently reused, and the water pressure in the hot water buffer tank 3 and the hot water buffer tank 4 can be maintained at a constant level.

  A steam supply control valve and a hot water buffer tank temperature control device 114 are provided, and when the temperature measured by the temperature sensor provided in the hot water supply pipe 7 becomes a predetermined value or less, the opening of the steam supply control valve is increased. When the temperature exceeded a predetermined value, the opening of the steam supply control valve was reduced. Thereby, when the temperature of the warm water in the warm water supply pipe 7 becomes a predetermined value or less, the amount of steam supplied to the first warm water buffer tank 3 and the second warm water buffer tank 4 is increased, and the temperature of the warm water is raised. be able to. When the temperature of the hot water in the hot water supply pipe 7 becomes equal to or higher than a predetermined value, the amount of steam supplied to the first hot water buffer tank 3 and the second hot water buffer tank 4 can be reduced. Therefore, the temperature of the hot water supplied to the LNG vaporizer 2 can be kept constant.

  As mentioned above, although embodiment of this invention was described, it only showed the specific example and does not specifically limit this invention. Further, the effects described in the embodiments of the present invention only list the most preferable effects resulting from the present invention, and the effects of the present invention are not limited to the effects described in the embodiments of the present invention.

DESCRIPTION OF SYMBOLS 1 LNG storage tank 2 LNG vaporizer 3 1st warm water buffer tank 4 2nd warm water buffer tank 5 1st discharge nozzle part 6 2nd discharge nozzle part 7, 7c Hot water supply pipe 7a, 7b Hot water supply pipe control valve 7d Bypass pipe 8 1st detection part 9 2nd detection part 10 Notification part 11 LNG satellite equipment control device 12 LNG supply pipe 13 NG supply pipe 14 Hot water generation part 15, 27a, 27b Hot water supply pipe 16 Steam generation part 17, 29a, 29b Steam supply pipe 18 Pump 19, 21, 22, 28a, 28b Hot water return pipe 20 Hot water return pipe control valve 23 First strainer 24 Second strainer 25 LNG flow pipe 26 Hot water flow pipe 30 Temperature sensor 31 Bypass pipe Control valve 100 LNG satellite equipment

Claims (3)

LNG satellite equipment for vaporizing LNG,
An LNG storage tank in which LNG is stored;
An LNG vaporizer that vaporizes LNG to generate gas;
A first hot water buffer tank and a second hot water buffer tank for storing hot water supplied to heat the LNG vaporizer;
A first discharge nozzle portion that is provided at a lower portion of the first hot water buffer tank and discharges the hot water;
A second discharge nozzle portion that is provided at a lower portion of the second hot water buffer tank and discharges the hot water;
The hot water discharged from the first hot water buffer tank through the first discharge nozzle and the hot water discharged from the second hot water buffer tank through the second discharge nozzle are the LNG vaporizer. A hot water supply pipe to supply to,
A first detector for detecting the water pressure in the first hot water buffer tank;
A second detector for detecting the water pressure in the second hot water buffer tank;
A notification unit for notifying an abnormality in the flow of hot water supplied to the LNG vaporizer;
When the difference between the value of the first water pressure detected from the first detection unit and the value of the second water pressure detected from the second detection unit is equal to or greater than a predetermined value, the notification unit is abnormal. An LNG satellite facility comprising: A first strainer attached to the first discharge nozzle portion and arranged to protrude inward of the first hot water buffer tank;
2. The LNG satellite facility according to claim 1, further comprising: a second strainer attached to the second discharge nozzle portion and arranged to protrude inward of the second hot water buffer tank.   3. The LNG satellite facility according to claim 2, wherein each of the first strainer and the second strainer has a cylindrical shape, and a mesh member is disposed on a circumferential surface of the cylindrical shape.

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