KR20230061619A - Warming up system of LNG cargo tank maintenance - Google Patents

Abstract

A warm-up system for an LNG storage tank is disclosed. According to one aspect of the present invention, in the tank warming up system of a ship equipped with a plurality of LNG storage tanks, the gas supply line connected to the LNG storage tank; a compression unit provided on the gas supply line and compressing BOG (Boil Off Gas) generated in the LNG storage tank; a heater receiving the compressed natural gas through the compression unit, heating it to a predetermined temperature, and supplying the compressed natural gas to at least one of the LNG storage tanks; And by receiving and vaporizing the compressed natural gas through the compression unit, the LNG A warm-up system for an LNG storage tank including a vaporizer supplied to at least one of the storage tanks may be provided.

Description

Warming up system of LNG cargo tank maintenance}

The present invention relates to a warming-up system for an LNG storage tank, and more particularly, to a warming-up system for an LNG storage tank for warming up the tank prior to maintenance of the LNG storage tank of a ship.

In general, liquefied natural gas (hereinafter referred to as 'LNG') is a colorless, odorless, and transparent liquid obtained by liquefying natural gas (NG) whose main component is methane by cooling it to about -162 ° C. As such, it has a volume of about 1/600 of that of natural gas.

Such LNG is stored in an LNG regasification vessel (RV) or a storage tank (commonly referred to as a 'cargo hold') provided in an LNG carrier that can withstand low temperatures, and is transported to a consumer.

In recent years LNG FPSO (Floating, production, Storage and offloading) or LNG FSRUs (Floating Storage and Regasification Unit), the demand for floating offshore structures is gradually increasing, and these floating offshore structures also include storage tanks installed in LNG carriers or LNG RVs.

A gas trial is conducted to verify the operation of various facilities and devices provided on such floating offshore structures or LNG carriers, and in the case of LNG storage tanks provided on ships, maintenance during gas trial runs is being done In addition, in the case of the LNG storage tank of the carrier, maintenance is performed regularly at a predetermined cycle, for example, every 2.5 to 5 years.

To this end, all remaining LNG remaining in the storage tank may be treated, and maintenance may be performed at the repair terminal.

Prior to maintenance of the tank, it is necessary to warm up the tank and perform an inerting operation by supplying an inert gas.

In addition, the gas remaining inside the storage tank is replaced with air, and the temperature inside the storage tank is changed to a temperature at which the operator can work. .

A method of warming up the tank by preparing a compressor to warm up the tank, compressing the natural gas, and then heating it with a heater can be considered. A heater that can do this should be used.

However, a heater capable of handling a high load area is advantageous in the initial high load area for warming up of the tank, but as the internal temperature of the tank rises over time, the load of the heater decreases, making it unnecessary to use a large capacity heater. Of course, there is a problem of increasing cost.

Patent Publication 10-2013-0064194 (Samsung Heavy Industries Co., Ltd.) 2013. 06. 18

The warming-up system for an LNG storage tank according to an embodiment of the present invention configures the system so that a vaporizer is used for pre-heater when warming up the tank prior to maintenance of the LNG storage tank of the ship, can be designed for low load.

According to one aspect of the present invention, in the tank warming up system of a ship equipped with a plurality of LNG storage tanks, the gas supply line connected to the LNG storage tank; a compression unit provided on the gas supply line and compressing BOG (Boil Off Gas) generated in the LNG storage tank; a heater receiving the compressed natural gas through the compression unit, heating it to a predetermined temperature, and supplying the compressed natural gas to at least one of the LNG storage tanks; And by receiving and vaporizing the compressed natural gas through the compression unit, the LNG A warm-up system for an LNG storage tank including a vaporizer supplied to at least one of the storage tanks may be provided.

In addition, in the initial stage of warming up of the LNG storage tank, the heater and the vaporizer are operated together, and when the internal temperature of the LNG storage tank reaches a preset temperature value, the compressed natural gas is delivered to the heater through the vaporizer. Alternatively, one of the heater and vaporizer may be selected and operated.

In addition, the compressed natural gas discharged from the outlet of the compression unit is branched from a first compressed gas supply line connected to the outlet of the compression unit and the heater and the first compressed gas supply line so that the compressed natural gas is supplied to the heater and the vaporizer, respectively. It may include a second compressed gas supply line connected to the vaporizer.

In addition, on-off valves for controlling the flow of the compressed natural gas to the heater and the vaporizer may be provided in the first and second compressed gas supply lines, respectively.

In addition, a recovery line for supplying the natural gas heated by the heater to at least one of the plurality of LNG storage tanks may be further included.

In addition, a first connection line connected to the recovery line and a second connection line branched off from the first connection line and connected to the first compressed gas supply line may be provided at the discharge end of the vaporizer.

In addition, a first flange pipe for temperature control is provided at the discharge end of the heater, and the compressed natural gas is branched from the first compressed gas supply line so that the compressed natural gas is supplied to the first flange pipe without passing through the heater. A first branch line connected to the first flange pipe may be further provided.

In addition, an on/off valve may be provided in the first branch line. In addition, a second flange pipe for temperature control is provided at the discharge end of the vaporizer, and the compressed natural gas does not pass through the vaporizer, and the second flange pipe is provided. A second branch line branched from the second compressed gas supply line to be supplied to the second flange pipe and connected to the second flange pipe may be further provided.

In addition, a pump provided in the LNG storage tank may be further provided, and LNG remaining in the LNG storage tank may be provided to be delivered to the vaporizer through the pump.

In addition, a pump connection line connecting the pump and the vaporizer may be connected to the second compressed gas supply line.

The warming-up system of an LNG storage tank according to an embodiment of the present invention configures the system so that a vaporizer is used for pre-heating when warming up the tank prior to maintenance of the storage tank, thereby reducing the load on the heater. It has effects that can be designed for use. Accordingly, cost can be reduced, and it is also advantageous in terms of securing space in the ship.

In addition, there is an effect that maintenance can be performed at sea without the need to return to a repair terminal for maintenance of a ship or floating offshore structure.

The present invention will be specifically described by the drawings below, but since these drawings show preferred embodiments of the present invention, the technical spirit of the present invention should not be construed as being limited to the drawings.
1 is a diagram showing a schematic configuration of a warming-up system for an LNG storage tank according to an embodiment of the present invention.
2 is a diagram showing a schematic configuration of a warming-up system for an LNG storage tank according to another embodiment of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a diagram showing a schematic configuration of a warming-up system for an LNG storage tank according to an embodiment of the present invention.

Referring to FIG. 1, the warming-up system for an LNG storage tank according to the present invention includes a compression unit 100 for compressing BOG (Boil Off Gas) generated in a plurality of LNG storage tanks (CT) provided on a ship, and a compression unit The compressed natural gas is delivered through the heater 200 that receives the compressed natural gas through the 100, heats it to a predetermined temperature, and supplies it to at least one of the plurality of LNG storage tanks (CT) and the compression unit 100. Receive and vaporize multiple LNG The tank is warmed up by including the vaporizer 300 supplied to at least one of the storage tanks (CT).

In the warming-up system of the LNG storage tank, the heater 200 and the vaporizer 300 are operated together at the initial warm-up stage of the LNG storage tank (CT), and the internal temperature of the LNG storage tank (CT) reaches a preset temperature value. In this case, the compressed natural gas may be transmitted to the heater 200 through the vaporizer 300, or the heater 200 and the vaporizer 300 may be selected and operated.

In addition, in the warming-up system of the LNG storage tank according to the present invention, the compressed natural gas discharged from the gas supply line 10 connected to the LNG storage tank (CT) and the outlet end of the compression unit 100 is supplied to the heater 200. ) And the first compressed gas supply line 21 and the second compressed gas supply line 22 provided to be supplied to the vaporizer 300, respectively, and the natural gas heated through the heater 200 is supplied to a plurality of LNG storage tanks (CT The recovery line 20 supplied to at least one of ), the first connection line 31 connecting the discharge end of the vaporizer 300 and the recovery line 20, and branched off from the first connection line 31, 1 includes a second connection line 32 connected to the compressed gas supply line 21.

In this embodiment, the ship is a general term for offshore structures that operate on the sea or float on the sea, and produce liquefied natural gas by liquefying natural gas or a ship equipped with an LNG storage tank (CT) for storing LNG. doing, storing and unloading LNG-FPSO (Floating Production Storage Offloading) days number but, that In addition, LNG-FSRU (Floating Storage and Regasification Unit), LNG-RV (Regasification Vessel) and the like may all be included.

Ships such as LNG-FPSO operating at sea are equipped with many equipment, and the device configuration is very complex and expensive, and once installed in an offshore gas field, it operates 24/7 for a long period of time up to several decades. Therefore, prior to delivery to the ship owner, a gas trial is conducted at the ship's built site or in the nearby sea, checking malfunctions of various devices and systems, adjusting operation under cryogenic conditions, and testing process performance.

During such a test run, LNG is vaporized to supply natural gas, while liquefaction process facilities of the ship are inspected and maintenance of the LNG storage tank is also performed. In order to maintain the LNG storage tank, the LNG inside the tank is discharged to the outside, and the temperature of the LNG storage tank in which the cryogenic LNG is stored is raised and inactivated.

Looking more closely at this, Corresponding LNG to be maintained Prior to maintenance, the storage tank (CT) discharges LNG, The temperature of the natural gas is raised and supplied to the tank to warm up. Warming with natural gas until the tank reaches a constant temperature up after, inert with gas again warming up up inert gas to the tank by supplying LNG storage tank (CT) Inerting. After that, after going through the aeration process, the LNG storage tank (CT) is maintained.

In order to supply natural gas for warming up of the LNG storage tank (CT) as a previous stage of such maintenance, the present embodiment heats the natural gas compressed by the compression unit 100 with the heater 200 to correspond to the LNG. The LNG is supplied to the storage tank (CT) or compressed natural gas is vaporized through the vaporizer (300). It is supplied to the storage tank (CT). At this time, the natural gas heated in the heater 200 and the natural gas vaporized in the vaporizer 300 are LNG It is supplied to the bottom of the storage tank (CT).

The compression unit 100 receives BOG or natural gas from the gas supply line 10 connected to the LNG storage tank (CT) and compresses it. At this time, the compression unit 100 may be provided as a high duty (HD) compressor to compress natural gas. The natural gas compressed through the compression unit 100 is provided to be delivered to the heater 200 and the vaporizer 300, respectively. Accordingly, the first compressed gas supply line 21 is connected to the outlet end of the compression unit 100 and the heater 200, and the second compressed gas supply line 22 branches from the first compressed gas supply line 21. It is connected to the vaporizer 300. At this time, the heater 200 and the vaporizer 300 are provided in parallel and operated together. After that, when the internal temperature of the LNG storage tank (CT) is warmed up to a predetermined temperature, natural gas is supplied to the heater through the vaporizer 300. 200, or select and operate either one of the heater 200 and the vaporizer 300. These operating conditions will be described again below.

Meanwhile, in the initial stage of warm-up, the heater 200 and the vaporizer 300 are simultaneously operated to bring the LNG storage tank CT to a required temperature within a certain period of time. That is, it is possible to increase the capacity by passing the compressed natural gas delivered through the compression unit 100 to the heater 200 and the vaporizer 300, respectively. Accordingly, it is possible to reduce the specifications of the heater 200 according to the present invention compared to the conventional heater, thereby reducing costs and enabling efficient operation.

The first compressed gas supply line 21 and the second compressed gas supply line 22 are provided with first and second open/close valves V1 and V2, respectively. These on-off valves (V1, V2) are selectively opened or closed according to requirements to control the flow of natural gas. For example, in the initial stage of warm-up, the first on-off valve V1 provided on the first compressed gas supply line 21 and the second on-off valve V2 provided on the second compressed gas supply line 22 are opened. can

The heater 200 heats the compressed natural gas supplied through the first compressed gas supply line 21 and supplies it to the plurality of LNG storage tanks CT. Thus, the recovery line 20 is connected to the discharge end of the heater 200 and may be provided to be connected to a plurality of LNG storage tanks (CT). At this time, the recovery line 20 may be provided so that the natural gas heated by the heater 200 is supplied to the bottom of the LNG storage tank CT.

The vaporizer 300 may be provided to vaporize the compressed natural gas supplied through the second compressed gas supply line 22 and supply it to a plurality of LNG storage tanks (CT) or to the heater 300 . Accordingly, the discharge end of the vaporizer 300 is connected to the recovery line 20 through the first connection line 31, and the second connection line 32 branching off from the first connection line 31 is the first compressed gas. It may be provided to be connected to the supply line 21. The first connection line 31 and the second connection line 32 are provided with third and fourth opening and closing valves V3 and V4, respectively, to control the flow of natural gas according to the on/off of each opening and closing valve V3 and V4. will control For example, at the beginning of the warm-up, the fourth on-off valve V4 of the second connection line 32 is closed and the third on-off valve V3 of the first connection line 31 is opened to supply the vaporized natural gas to the recovery line ( 20) is provided so that it can be directly supplied to the LNG storage tank (CT).

According to one aspect of the present invention, a first flange pipe 210 for temperature control may be provided at the discharge end of the heater 200 . Accordingly, the first branch line branched from the first compressed gas supply line 21 and connected to the first flange pipe 210 so that the compressed natural gas is supplied to the first flange pipe 210 without passing through the heater 200. (23) may be further provided. The first branch line 23 is provided with a fifth on-off valve V5 for controlling the flow of natural gas through the first branch line 23 .

The first flange pipe 210 is for controlling the temperature of natural gas delivered to the LNG storage tank (CT), and a temperature sensor (not shown) may be provided therein. For example, when the temperature of the natural gas heated by the heater 200 is higher than the target value, the fifth on-off valve V5 provided in the first branch line 23 is opened to supply natural gas to the first flange pipe 210. ) will be supplied. In addition, it may be provided that natural gas is supplied only through the first branch line 23 . Accordingly, a sixth on-off valve V6 is provided on the downstream side of the first compressed gas supply line 21 at the portion where the first branch line 23 is connected. In addition, it is preferable that the sixth on-off valve (V6) and the first branch line 23 are provided on the downstream side of the part where the second connection line 32 is connected so that the natural gas delivered from the vaporizer 300 can be supplied. do.

In addition, a second flange pipe 310 for temperature control may be provided at the discharge end of the vaporizer 300 . Accordingly, a second branch line branched from the second compressed gas supply line 22 and connected to the second flange pipe 310 so that the compressed natural gas is supplied to the second flange pipe 310 without passing through the vaporizer 300. (24) may be further provided. The second branch line 24 is provided with a seventh on-off valve V7 for controlling the flow of natural gas through the second branch line 24 .

The second flange pipe 310 is for controlling the temperature of the natural gas delivered to the LNG storage tank (CT) or the heater 200, and a temperature sensor (not shown) may be provided therein. For example, when the temperature of the natural gas vaporized through the vaporizer 30 is higher than the target value, the seventh on-off valve V7 provided in the second branch line 24 is opened to supply natural gas to the second flange pipe 310. ) will be supplied. In addition, it may be provided that natural gas is supplied only through the second branch line 24 . That is, by closing the second on-off valve V2 provided on the second compressed gas supply line 22 and opening the seventh on-off valve V7 provided on the second branch line 24, the compressed natural gas is produced. 2 can be directly transmitted to the flange pipe (310).

Meanwhile, unexplained reference numeral '110' denotes a vent mast. This vent mast 110 is connected to the gas supply line 10 located at the discharge end of the LNG storage tank (CT), so that steam can be exhausted when the internal pressure of the LNG storage tank (CT) is higher than the set pressure. A pressure control valve 111 is provided.

As described above, the warm-up system of the LNG storage tank (CT) supplies the compressed natural gas through the compression unit 100 to the heater 200 and the vaporizer 300, respectively, at the beginning of the warm-up to increase the temperature of the natural gas. Warm up by raising the water and supplying it to the tank. Through this warm-up operation, the cryogenic natural gas, which is an initial high-load region, is heated to a certain temperature, for example, 0° C., after which the load is gradually reduced. Accordingly, in a parallel method of supplying compressed natural gas to the heater 200 and the vaporizer 300, the natural gas is delivered to the heater 200 through the vaporizer 300 or either the heater 200 or the vaporizer 300 It can be converted into a serial method in which one is selected and operated. For example, the first on-off valve V1 on the first compressed gas supply line 21 is closed so that the natural gas delivered through the compression unit 100 is delivered only to the second compressed gas supply line 22, Natural gas through the vaporizer 300 can be controlled so that the third on-off valve V3 is closed and the fourth on-off valve V4 is opened to be supplied to the heater 200 through the second connection line 32.

On the other hand, tank warm-up through natural gas is performed prior to the step of inerting by supplying nitrogen gas for maintenance of the LNG storage tank (CT). For example, tank warm-up by natural gas is This can be done until the internal temperature reaches -40 °C. When the temperature inside the tank exceeds -40 ° C, after warming up with nitrogen gas, nitrogen gas is supplied to the LNG storage tank (CT) to inactivate it.

A nitrogen gas generator (not shown) for warming up and inactivating the nitrogen gas may be provided in the ship, and the nitrogen gas generated from the nitrogen gas generator is introduced into the vaporizer 300 to be vaporized, and then the LNG storage tank (CT) ) to warm up the tank.

Although the warming-up system of the LNG storage tank according to one aspect of the present invention has been shown and described as supplying compressed natural gas to the vaporizer 300 through the compression unit 100, it is not limited thereto, and the LNG storage tank (CT ) The tank may be warmed up by supplying the remaining LNG to the vaporizer 300. Such a warming-up system for an LNG storage tank according to another embodiment of the present invention is shown in FIG. 2 . FIG. 2 is a diagram showing a schematic configuration of a warming-up system for an LNG storage tank according to another embodiment of the present invention. Here, the same reference numerals as in the previously shown drawings indicate members performing the same functions.

Referring to FIG. 2, the warming-up system of the LNG storage tank according to the present embodiment, compared to the previous embodiment, connects the pump 400 provided in the LNG storage tank (CT) and the pump 400 and the vaporizer 300. A pump connection line 40 is further provided.

The pump 400 is a submerged cryogenic pump, and serves to deliver remaining LNG to the vaporizer 300 when the inside of the LNG storage tank (CT) is emptied. At this time, according to the drawing, the pump 400 is shown as being provided only in two of the four LNG storage tanks (CT), but is provided in each of the four LNG storage tanks (CT), and the pump connection line ( 40) can be linked.

The pump connection line 40 may be connected to the pump 400 and the second compressed gas supply line 22 . Accordingly, LNG supplied through the pump connection line 40 is vaporized through the vaporizer 300 and then supplied to the LNG storage tank CT through the first connection line 31 and the recovery line 20 or connected to the second connection. It may be supplied to the heater 200 through the line 32 . An eighth on-off valve V8 for controlling the flow of LNG is provided in the pump connection line 40.

In addition, a third branch line 43 branched from the pump connection line 40 and connected to the second branch line 24 so that LNG supplied through the pump 400 is directly delivered to the second flange pipe 310. more can be provided. The third branch line 43 is provided to be connected to the inlet side of the second flange pipe 310, and controls the flow of LNG through the ninth on-off valve V9 provided on the third branch line 43. provided

The above embodiment may be operated when there is remaining LNG in the LNG storage tank (CT), and the process of warming up the tank may be performed through the same process as in the previous embodiment.

As described in these embodiments, by independently operating the heater 200 and the vaporizer 300 to warm up the tank, the specifications of the heater 200 can be reduced, thereby reducing costs and enabling efficient operation will do

As described above, although the present invention has been described by the limited embodiments and drawings, the present invention is not limited thereto, and the technical spirit of the present invention and the following by those skilled in the art to which the present invention belongs Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

10: gas supply line
20: recovery line
21: first compressed gas supply line
22: second compressed gas supply line
31: first connection line
32: second connection line
40: pump connection line
100: compression unit
200: heater
300: carburetor
400: pump

Claims (10)

In the tank warming up system of a ship equipped with a plurality of LNG storage tanks,
a gas supply line connected to the LNG storage tank;
a compression unit provided on the gas supply line and compressing BOG (Boil Off Gas) generated in the LNG storage tank;
a heater receiving the compressed natural gas through the compression unit, heating it to a predetermined temperature, and supplying the compressed natural gas to at least one of the LNG storage tanks; and
The compressed natural gas is received and vaporized through the compression unit, so that the LNG A warm-up system for an LNG storage tank comprising a; vaporizer supplied to at least one of the storage tanks. According to claim 1,
In the initial stage of warming up of the LNG storage tank, the heater and the vaporizer are operated together, and when the internal temperature of the LNG storage tank reaches a preset temperature value, the compressed natural gas is delivered to the heater through the vaporizer or the A warm-up system for an LNG storage tank that selects and operates either a heater or a vaporizer. According to claim 1,
A first compressed gas supply line connected to the outlet of the compression unit and the heater and branched off from the first compressed gas supply line so that compressed natural gas discharged from the outlet of the compression unit is supplied to the heater and the vaporizer, respectively. A warm-up system for an LNG storage tank including a second compressed gas supply line connected to. According to claim 3,
The warming-up system of the LNG storage tank in which the first and second compressed gas supply lines are provided with on-off valves for controlling the flow of compressed natural gas to the heater and the vaporizer, respectively. According to claim 3,
The warming-up system of the LNG storage tank further comprising a recovery line for supplying the natural gas heated by the heater to at least one of the plurality of LNG storage tanks. According to claim 5,
The warming-up system of the LNG storage tank having a first connection line connected to the recovery line and a second connection line branched from the first connection line and connected to the first compressed gas supply line at the discharge end of the vaporizer. According to claim 3,
A first flange tube for temperature control is provided at the discharge end of the heater,
Warming of the LNG storage tank further comprising a first branch line branched from the first compressed gas supply line and connected to the first flange pipe so that the compressed natural gas is supplied to the first flange pipe without passing through the heater. up system. According to claim 3,
A second flange tube for temperature control is provided at the discharge end of the vaporizer,
Of the LNG storage tank further comprising a second branch line branched from the second compressed gas supply line and connected to the second flange pipe so that the compressed natural gas is supplied to the second flange pipe without passing through the vaporizer. warm-up system. According to claim 3,
Further comprising a pump provided in the LNG storage tank,
The warm-up system of the LNG storage tank, wherein the LNG remaining in the LNG storage tank is provided to be delivered to the vaporizer through the pump. According to claim 9,
The pump connection line connecting the pump and the vaporizer is a warm-up system for the LNG storage tank connected to the second compressed gas supply line.

Images