KR102017946B1 - A Regasification System and Vessel having the same - Google Patents

Abstract

Regasification system according to an embodiment of the present invention, a vaporizer for regasifying the liquefied gas by heat exchange with the intermediate heat medium; A plurality of intermediate heat medium pumps for supplying the intermediate heat medium; A plurality of intermediate heat medium heat exchangers for heating the intermediate heat medium; A plurality of heat source supply pumps for supplying heat to the plurality of intermediate heat exchangers; And an intermediate heat medium circulation line including the plurality of intermediate heat medium pumps and the plurality of intermediate heat medium heat exchangers, wherein the plurality of intermediate heat medium pumps and the plurality of heat source supply pumps are driven at least one variable frequency. .

Description

Regasification System and Vessel Having Same {A Regasification System and Vessel having the same}

The present invention relates to a regasification system and a vessel comprising the same.

In general, LNG is known to be a clean fuel and abundant reserves than petroleum, and its use is rapidly increasing with the development of mining and transport technology. It is common to store LNG in liquid state by reducing the temperature of methane, its main component, to below -162 at 1 atm, and the volume of liquefied methane is about 1/600 of the volume of gaseous methane in the standard state. 0.42, about one-half the share of crude oil.

LNG is liquefied for ease of transportation and vaporized at the point of use after transportation. However, there are concerns about the installation of LNG vaporization facilities onshore due to the risk of natural disasters and terrorism.

Therefore, instead of the conventional liquefied natural gas regasification system installed on land, a vessel that supplies natural gas vaporized to the land by installing a regasification device on an LNG carrier carrying liquefied natural gas (Liquefied Natural Gas) LNG FSRU, for example, is in the spotlight.

In a ship including such an LNG regasification apparatus, various researches and developments have been made to efficiently drive a supply device of a heat source for vaporizing LNG.

The present invention has been made to improve the prior art, an object of the present invention, the regasification system that can reduce the energy consumed to supply the unnecessary fruit by optimally supplying the fruit to supply the regasification apparatus and the same It is to provide a shipping vessel.

Regasification system according to an embodiment of the present invention, a vaporizer for regasifying the liquefied gas by heat exchange with the intermediate heat medium; A plurality of intermediate heat medium pumps for supplying the intermediate heat medium; A plurality of intermediate heat medium heat exchangers for heating the intermediate heat medium; A plurality of heat source supply pumps for supplying heat to the plurality of intermediate heat exchangers; And an intermediate heat medium circulation line including the plurality of intermediate heat medium pumps and the plurality of intermediate heat medium heat exchangers, wherein the plurality of intermediate heat medium pumps and the plurality of heat source supply pumps are driven at least one variable frequency. .

Specifically, both the plurality of intermediate heat pumps and the heat source supply pump may be variable frequency driven (VFD).

Specifically, in the plurality of intermediate heat medium pumps and the plurality of heat source supply pumps, only one intermediate heat medium pump or one heat source supply pump may be variable frequency driven (VFD).

Specifically, the control unit may further include a first control unit controlling the plurality of intermediate heat medium pumps according to the temperature of the liquefied gas discharged from the vaporizer or the temperature of the intermediate heat medium discharged from the vaporizer.

Specifically, when the temperature of any one of the temperature of the intermediate heat medium discharged from the vaporizer or the temperature of the liquefied gas discharged from the vaporizer is increased, the first control unit controls a variable frequency drive among the plurality of intermediate heat medium pumps (VFD). If the temperature of the intermediate heat medium discharged from the vaporizer or the temperature of the liquefied gas discharged from the vaporizer decreases, the variable flow rate of the plurality of intermediate heat medium pumps may be controlled. VFD) can be controlled to increase the drive flow rate of the pump being.

Specifically, the method may further include a second control unit controlling the plurality of heat source supply pumps according to the temperature of the fruit discharged from the intermediate heat exchanger.

Specifically, when the temperature of the fruit discharged from the intermediate heat medium heat exchanger increases, the second control unit controls to reduce the drive flow rate of the variable frequency drive (VFD) pump of the plurality of heat source supply pumps, When the temperature of the fruit discharged from the heat medium heat exchanger decreases, it is possible to control to increase the driving flow rate of the variable frequency drive (VFD) of the plurality of heat source supply pump.

Specifically, the intermediate heat medium circulation line for circulating the intermediate heat medium to the vaporizer, the plurality of intermediate heat medium pumps, the plurality of intermediate heat medium heat exchangers and the plurality of heat source supply pumps; And a plurality of intermediate heat medium pump lines branched on the intermediate heat medium circulation line and formed to include the plurality of intermediate heat medium pumps, respectively.

Specifically, the plurality of intermediate heat medium pump lines may be connected in parallel with each other.

Specifically, when the vaporizer is called a first vaporizer, a first train including the first vaporizer; And a second train including a second vaporizer for vaporizing the liquefied gas by heat exchange with the intermediate heat medium, wherein the plurality of intermediate heat medium pump lines may be connected to each of the first train and the second train. .

Specifically, a plurality of sharing lines for connecting and sharing the plurality of intermediate heat medium pump line with each other; A plurality of control valves provided on the plurality of sharing lines to control the flow of the intermediate heating medium; And a third control unit which controls the opening degree of the plurality of control valves when the plurality of intermediate heat medium pumps are malfunctioning or stopped, wherein the third control unit comprises: at least one of the plurality of intermediate heat medium pumps malfunctioning or stopping At least one of the control valve to stop the malfunction or stopped pump of the plurality of intermediate heat medium pump, and to supply the intermediate heat medium to the intermediate heat medium pump line equipped with the malfunction or stopped pump of the plurality of control valves The opening of the control valve can be controlled to open.

Specifically, it may be a ship comprising the regasification system.

The regasification system and the ship including the same according to the present invention has the effect of reducing the energy consumed for supplying the unnecessary fruit by optimally supplying the fruit to be supplied to the regasification device.

1 is a conceptual diagram of a ship having a regasification system according to an embodiment of the present invention.
2 is a conceptual diagram of a part of a regasification system according to a first embodiment of the present invention.
3 is a conceptual diagram of a part of a regasification system according to a second exemplary embodiment of the present invention.
4 is a conceptual diagram of a part of a regasification system according to a third exemplary embodiment of the present invention.
FIG. 5 is a comparison chart illustrating a power consumption comparison and an effect comparison for driving the pumps according to the first to third embodiments in the regasification system according to the embodiment of the present invention.

The objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and the preferred embodiments associated with the accompanying drawings. In the present specification, in adding reference numerals to the components of each drawing, it should be noted that the same components as possible, even if displayed on different drawings have the same number as possible. In addition, in describing the present invention, if it is determined that the detailed description of the related known technology may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

Hereinafter, in the present specification, liquefied gas may be used to encompass all gaseous fuels which are generally stored in a liquid state, such as LNG or LPG, ethylene, ammonia, and the like. Can be expressed as This can be applied to the boil-off gas as well. In addition, LNG may be used for the purpose of encompassing not only liquid NG (Natural Gas) but also supercritical NG for convenience, and evaporation gas may be used to include not only gaseous evaporation gas but also liquefied evaporation gas. Can be.

The contents of the present specification may be a description of at least one of the drawings included in the present specification, and the connection between the contents and the drawings is not limited to a level that can be understood by those skilled in the art. Be aware that it can be done.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a conceptual diagram of a vessel 100 having a regasification system 1, 2, 3 according to an embodiment of the invention.

As shown in FIG. 1, a vessel 100 having regasification systems 1, 2, and 3 includes a liquefied gas storage tank 10, a feeding pump 20, a boosting pump 21, and a suction drum ( 30, a vaporizer 40, a trim heater 41, an evaporative gas compressor 50, a first demand destination 61, and a second demand destination 62.

Here, the ship 100 in which the regasification system 1, 2, 3 is installed is a hull H composed of a bow (not shown), a stern (not shown), and an upper deck (not shown). It propagates by the propeller shaft S which propagates the power produced by the engine E of the engine room (not shown) arrange | positioned at the stern part, and operates it by propeller shaft P operating.

In addition, the vessel 100 is a liquefied gas provided with the regasification system (1, 2, 3) in the liquefied gas carrier ship 100 in order to re-liquefy the liquefied gas at sea to supply the liquefied gas to the land terminal It may be a regasification vessel (LNG RV) or a floating liquefied gas storage and regasification plant (FSRU).

Hereinafter, a regasification system 1, 2, 3 according to an embodiment of the present invention will be described with reference to FIG. 1.

Regasification system (1, 2, 3) according to an embodiment of the present invention, the liquefied gas in the liquid state from the liquefied gas storage tank 10 through the feeding pump 20 through the suction drum 30 via the boosting pump After pressurizing with (21), the liquefied gas is heated and regasified by the heat source in the vaporizer 40, and heated to the temperature required by the first demander 61 in the trim heater 41, and then the first demander 61 ) Is used. That is, in brief, the regasification system (1, 2, 3) of this invention uses the vaporizer 40 and the trim heater 41 to regasify liquefied gas, heats it up, and supplies it to the 1st demand source 61. As shown in FIG. . At this time, the boil-off gas generated in the liquefied gas storage tank 10 was pressurized by the boil-off gas compressor 50 and supplied to the second demand destination 62 for processing.

Prior to describing the individual configurations of the regasification system (1, 2, 3) according to the embodiment of the present invention, basic flow paths for organically connecting the individual configurations will be described. Here, the flow path may be a line through which the fluid flows, but is not limited thereto, and any flow path may be used.

In the embodiment of the present invention, it may further include a liquefied gas supply line (L1), regasification gas supply line (L2), boil-off gas supply line (L3). Each line may be provided with valves (not shown) that can adjust the opening degree, and the supply amount of the boil-off gas or liquefied gas may be controlled by adjusting the opening degree of each valve.

The liquefied gas supply line L1 connects the liquefied gas storage tank 10 and the suction drum 30 and includes a feeding pump 20 to feed the liquefied gas stored in the liquefied gas storage tank 10 to the feeding pump 20. It may be supplied to the suction drum 30 through the). In this case, the liquefied gas supply line L1 may be connected to the suction drum 30 and branched upstream of the suction drum 30 to be directly connected to the regasification gas supply line L2.

The regasification gas supply line L2 connects the suction drum 30 and the first demand destination 61 and includes a boosting pump 21, a vaporizer 40, and a trim heater 41, so as to provide a suction drum 30. The liquefied gas supplied directly from the liquefied gas or liquefied gas supply line (L1) temporarily stored in the pressurized by the boosting pump 21 and regasified by the vaporizer 40, and then heated up to the trim heater 41 to the first demand destination 61 ) Can be supplied.

The boil-off gas supply line L3 connects the liquefied gas storage tank 10 and the second demand destination 62 and includes an boil-off gas compressor 50 to store the boil-off gas generated in the liquefied gas storage tank 10. Pressurized by the boil-off gas compressor 50 can be supplied to the second demand (62).

Hereinafter, individual configurations that are organically formed by the lines L1 to L3 described above to implement the regasification systems 1, 2 and 3 will be described.

The liquefied gas storage tank 10 stores the liquefied gas to be supplied to the first demand destination 61. The liquefied gas storage tank 10 should store the liquefied gas in a liquid state. In this case, the liquefied gas storage tank 10 may have a pressure tank form.

Here, the liquefied gas storage tank 10 is disposed inside the hull H, and may be formed in four, for example, in front of the engine room. In addition, the liquefied gas storage tank 10 is, for example, a membrane type tank, but not limited thereto, and various types such as a stand-alone tank are not particularly limited.

The feeding pump 20 is provided on the liquefied gas supply line L1 and installed in or outside the liquefied gas storage tank 10 to suck the liquefied gas stored in the liquefied gas storage tank 10 to the suction drum 30. Can be supplied by

Specifically, the feeding pump 20 is provided between the liquefied gas storage tank 10 and the suction drum 30 on the liquefied gas supply line (L1) to primary liquefied gas stored in the liquefied gas storage tank 10 It may be pressurized and supplied to the suction drum 30.

The feeding pump 20 may pressurize the liquefied gas stored in the liquefied gas storage tank 10 to 6 to 8 bar and supply it to the suction drum 30. Here, the feeding pump 20 may pressurize the liquefied gas discharged from the liquefied gas storage tank 10 to increase the pressure and temperature slightly, and the pressurized liquefied gas may still be in a liquid state.

In this case, the feeding pump 20 may be a latent pump when provided inside the liquefied gas storage tank 10, and stored in the liquefied gas storage tank 10 when the feeding pump 20 is installed outside the liquefied gas storage tank 10. It may be provided at a position inside the hull H lower than the level of the liquefied gas and may be a centrifugal pump.

The boosting pump 21 may be provided between the suction drum 30 and the vaporizer 40 on the regasification gas supply line L2, and the liquefied gas or suction drum 30 supplied from the feeding pump 20. The liquefied gas supplied from the pressurized to 80 to 120bar can be supplied to the vaporizer 40.

The boosting pump 21 may pressurize the liquefied gas according to the pressure required by the first demand destination 61, and may be configured as a centrifugal pump.

The suction drum 30 may be connected to the liquefied gas supply line L1 to receive liquefied gas from the liquefied gas storage tank 10 and temporarily store the liquefied gas.

In detail, the suction drum 30 may receive the liquefied gas stored in the liquefied gas storage tank 10 from the feeding pump 20 through the liquefied gas supply line L1, and temporarily stores the liquefied gas supplied thereto. The liquefied gas may be separated into a liquid phase and a gaseous phase, and the separated liquid phase may be supplied to the boosting pump 21.

That is, the suction drum 30 temporarily stores the liquefied gas to separate the liquid phase and the gaseous phase, and then supplies the complete liquid phase to the boosting pump 21 so that the boosting pump 21 satisfies the effective suction head NPSH. Therefore, it is possible to prevent the cavitation (Cavitation) in the boosting pump (21).

The vaporizer 40 may be provided on the regasification gas supply line L2 to regasify the high pressure liquefied gas discharged from the boosting pump 21.

Specifically, the vaporizer 40 is provided on the regasification gas supply line L2 between the first demand destination 61 and the trim heater 41 and vaporizes the high pressure liquefied gas supplied from the boosting pump 21. After vaporizing to 40, it can be supplied to the trim heater 41.

Here, the vaporizer 40 may heat-reduce the liquefied gas by heat-exchanging the intermediate heat medium and the liquefied gas, and the intermediate heat medium may be propane, aqueous glycol water, or the like.

The trim heater 41 may be provided on the regasification gas supply line L2 to heat the regasified regasification gas discharged from the vaporizer 40.

Specifically, the trim heater 41 is provided on the regasification gas supply line L2 between the first demand destination 61 and the vaporizer 40, and is a high-pressure regasification regasification supplied from the vaporizer 41. The gas may be heated to a temperature required by the first demand source 60 and then supplied to the first demand destination 60.

Here, the trim heater 41 may heat the liquefied gas by heat-exchanging the intermediate heat medium and the liquefied gas, and the intermediate heat medium may be propane, glycol water aqueous solution, or the like.

The boil-off gas compressor 50 may pressurize the boil-off gas generated in the liquefied gas storage tank 10 and supply it to the second demand destination 62.

Specifically, the boil-off gas compressor 50 is provided on the boil-off gas supply line L3 to pressurize the boil-off gas generated in the liquefied gas storage tank 10 to about 6 to 8 bar or 6 to 15 bar, thereby providing a second demand source ( 62).

A plurality of boil-off gas compressors 50 may be provided to pressurize the boil-off gas in multiple stages. For example, three boil-off gas compressors 50 may be provided to pressurize the boil-off gas in three stages. The three stage compressor as an example here is just one example and is not limited to three stages.

In the embodiment of the present invention, each of the rear end of the boil-off gas compressor 50 may be provided with an boil-off gas cooler (not shown). When the boil-off gas is pressurized by the boil-off gas compressor 50, the temperature may also increase as the pressure increases, so in this embodiment, the boil-off gas may be lowered again using the boil-off gas cooler. The boil-off gas cooler may be installed in the same number as the boil-off gas compressor 50, and each boil-off gas cooler may be provided downstream of each boil-off gas compressor 50.

In addition, in the embodiment of the present invention, when the amount of boil-off gas generated in the liquefied gas storage tank 10 is rapidly increased by the boil-off gas compressor 50 is provided in parallel, all of them can be accommodated, or the boil-off gas compressor If one of the (50) is malfunctioning or shut down (Shut down), the other one of the boil-off gas compressor (50) can be operated to efficiently receive and treat the boil-off gas generated in the liquefied gas storage tank (10) Can be.

The first demand destination 61 can receive and consume the liquefied gas vaporized by the vaporizer 40. Here, the first demand destination 61 may vaporize the liquefied gas and receive and use the liquefied gas of the gaseous phase, and may be a land terminal installed on the land or a marine terminal floating on the sea.

The second demand destination 62 receives the boil-off gas generated from the liquefied gas storage tank 10 and uses it as fuel. In other words, the second demand destination 62 requires the boil-off gas and can be driven by using it as a raw material. The second demand source 62 may be a power generation engine (for example, DFDG), a gas combustion device (GCU), or a boiler (for example, a boiler for generating steam), but is not limited thereto.

Specifically, the second demand source 62 is connected to the boil-off gas supply line L3 to receive the boil-off gas and pressurizes the boil-off gas pressurized to a low pressure of about 1 to 6 bar (max. 15 bar) by the boil-off gas compressor 50. Can be supplied and used as fuel.

In addition, the second demand source 62 may be a heterogeneous fuel engine capable of using heterogeneous fuels, so that not only the evaporated gas but also oil may be used as the fuel, but the evaporated gas or the oil is not supplied and the evaporated gas or the oil is selectively supplied. Can be supplied. This is to prevent two materials having different combustion temperatures from being mixed and supplied, thereby preventing the efficiency of the second demand source 62 from dropping.

Here, the second demand destination 62 may be provided on a deck (not shown) of the engine room provided inside the stern portion.

Hereinafter, the regasification system 1 according to the first embodiment of the present invention will be described in detail with reference to FIG. 2.

2 is a conceptual diagram of a part of a regasification system according to a first embodiment of the present invention.

As shown in FIG. 2, in the regasification system 1 according to the first embodiment of the present invention, the suction drum 30, the boosting pump 21, the vaporizer 40, the trim heater 41, and the first Demand destination 61, seawater heat exchanger 42a-42c, intermediate heat medium pump 43a-43c, sea water pump 44a-44f, intermediate heat medium circulation line GL, first to third intermediate heat medium pump lines GL1 GL3), seawater supply line SL, first to third temperature sensors T1 to T3, flow sensor F, first to ninth control valves B1 to B9, and first and second control units Not shown).

In the first embodiment of the present invention, the suction drum 30, the boosting pump 21, the carburetor 40, the trim heater 41, and the first consumer 61 are replaced with those described above, hereinafter. The components other than the suction drum 30, the boosting pump 21, the vaporizer 40, the trim heater 41, and the first demand destination 61 will be described in detail. Here, the seawater heat exchangers 42a to 42c may be referred to as intermediate heat exchanger heat exchangers, and the seawater pumps 44a to 44f may be referred to as heat source supply pumps.

Further, in the first embodiment of the present invention, up to the vaporizer 40 and the trim heater 41 as the first train or the suction drum 30, the boosting pump 21, the vaporizer 40 and the trim heater 41. Can be named as the first train.

In this case, in the first embodiment of the present invention, the regasification gas supply line L2 branches in parallel upstream of the suction drum 30, so that the suction drum 30, the boosting pump 21, and the vaporizer 40 are separated. And a second train A1 for forming components having the same structure as the trim heater 41 in parallel with the first train, and a third train A2 having the same parallel structure as well. Can be.

A plurality of seawater heat exchangers 42a to 42c are provided to heat the intermediate heat medium, and may be provided in parallel between the vaporizer 40 and the intermediate heat medium pumps 43a to 43c on the intermediate heat medium circulation line GL. .

Further, the seawater heat exchangers 42a to 42c are provided downstream of the seawater pumps 44a to 44f on the seawater supply line SL, and receive seawater from the seawater supply line SL, and then from the intermediate heat medium circulation line GL. The intermediate heat medium supplied may be heat-exchanged to transfer heat of seawater to the intermediate heat medium.

That is, the seawater heat exchangers 42a to 42c can receive seawater and heat the intermediate heat medium.

The intermediate heat medium pumps 43a to 43c are provided in plural in parallel on the intermediate heat medium circulation line GL to supply the intermediate heat medium so that the intermediate heat medium circulates on the intermediate heat medium circulation line GL, and at least one variable frequency drive ( VFD). Here, the intermediate heat medium pumps 43a to 43c may all be driven at variable frequencies, for example, and three may be provided as an example. (The number of intermediate heat medium pumps 43a-43c is of course not limited to three.)

Specifically, the intermediate heat medium pumps 43a to 43c may be branched between the seawater heat exchangers 42a to 42c and the trim heater 41 on the intermediate heat medium circulation line GL, and may be formed in parallel to each other. Each of the heating medium pump lines GL1 to GL3 may be connected to the first control unit to be described later in a wired or wireless manner and may receive a control command from the first control unit to be variable frequency drive (VFD).

The plurality of seawater pumps 44a to 44f are provided in parallel on the seawater supply line SL to supply heat (seawater) to the seawater heat exchangers 42a to 42c, and at least one variable frequency drive VFD is performed. Here, the seawater pumps 44a to 44f may all be variable frequency driven as an example, and six may be provided as an example. (The number of the seawater pumps 44a to 44f is not limited to six, of course. .)

Specifically, the seawater pumps 44a to 44f may be formed in parallel between the sea chest SC and the seawater heat exchanger 42a to 42c on the seawater supply line SL, and may be wired with the first control unit to be described later. Alternatively, the variable frequency drive (VFD) may be wirelessly connected and receive a control command from the first controller.

The intermediate heat medium circulation line GL is provided with a vaporizer 40, a trim heater 41, a seawater heat exchanger 42a to 42c, and an intermediate heat medium pump 43a to 43c, and the intermediate heat medium is trim heater 41, It can be circulated by the vaporizer | carburetor 40, the seawater heat exchanger 42a-42c, and the intermediate heat medium pump 43a-43c.

In this case, the intermediate heat medium circulation line GL may be connected to each of the first train to the third train in parallel.

The first to third intermediate heat medium pump lines GL1 to GL3 are branched between the seawater heat exchangers 42a to 42c and the trim heaters 41 on the intermediate heat medium circulation line GL and formed in parallel, respectively. 43a-43c can be provided.

The seawater supply line SL connects the sea chest SC and the overboard, and may include seawater heat exchangers 42a to 42c.

The first to third temperature sensors T1 to T3 are provided on the regasification gas supply line L2, the intermediate heat medium circulation line GL, and the seawater supply line SL, respectively, and the regasification gas supply line L2. The temperature of the liquefied gas flowing on the c), the temperature of the intermediate heat medium flowing on the intermediate heat medium circulation line (GL) or the temperature of the sea water flowing on the sea water supply line (SL) can be measured.

Specifically, the first temperature sensor T1 is provided between the first demand destination 61 and the trim heater 41 on the regasification gas supply line L2 and the temperature of the liquefied gas discharged from the trim heater 41. May be transmitted to the first control unit.

The second temperature sensor T2 is provided between the vaporizer 40 and the seawater heat exchanger 42a to 42c on the intermediate heat medium circulation line GL, and is discharged from the vaporizer 40 on the intermediate heat medium circulation line GL. The temperature of the intermediate heat medium can be transmitted to the first control unit.

The third temperature sensor T3 is provided between the seawater heat exchanger 42a to 42c and the overboard on the seawater supply line SL, and the seawater heat exchanger 42a to 42c on the seawater supply line SL. The temperature of the seawater discharged from can be transmitted to the second control unit.

In this case, the first to third temperature sensors T1 to T3 may be connected to the first control unit or the second control unit by wire or wirelessly to transmit temperature information of the liquefied gas or seawater to the first or second control unit.

The flow rate sensor F is provided on the regasification gas supply line L2, and can measure the flow volume of the liquefied gas flowing on the regasification gas supply line L2.

Specifically, the flow sensor F is provided between the vaporizer 40 and the boosting pump 21 on the regasification gas supply line (L2), the flow rate of the liquefied gas flowing into the vaporizer 40 to the first control unit I can send it.

In this case, the flow rate sensor F may be connected to the first control unit by wire or wirelessly to transmit flow rate information of the liquefied gas to the first control unit.

The first to ninth control valves B1 to B9 are provided downstream of the intermediate heat medium pumps 43a to 43c or downstream of the sea water pumps 44a to 44f, respectively, and are discharged from the intermediate heat medium pumps 43a to 43c. Can be controlled or the flow rate of the seawater discharged from the seawater pumps 44a to 44f can be controlled.

For example, in the exemplary embodiment of the present invention, all of the first to ninth control valves B1 to B9 may be remote throttling valves.

The first control unit may control the plurality of intermediate heat medium pumps 43a to 43c according to the temperature of the liquefied gas discharged from the vaporizer 40 or the temperature of the intermediate heat medium discharged from the vaporizer 40.

In this case, the first control unit may receive the temperature of the liquefied gas discharged from the vaporizer 40 (specifically, the trim heater 41) through the wire or wirelessly from the first temperature sensor T1, and the second temperature sensor The temperature of the intermediate heat medium discharged from the vaporizer 40 through wire or wireless from T2 may be received.

Specifically, when the temperature of any one of the temperature of the intermediate heat medium discharged from the vaporizer 40 or the temperature of the liquefied gas discharged from the vaporizer 40 (specifically, the trim heater 41) increases, a plurality of intermediate Among the heat medium pumps 43a to 43c, the drive flow rate of the variable frequency driven pumps 43a to 43c can be controlled to be reduced, and the temperature of the intermediate heat medium discharged from the carburetor 40 or the vaporizer 40; When the temperature of any one of the temperatures of the liquefied gas discharged from (41) decreases, it is possible to control to increase the driving flow rate of the variable frequency driven pumps 43a to 43c among the plurality of intermediate heat medium pumps 43a to 43c. have.

In addition, the first control unit may receive the flow rate of the liquefied gas flowing into the vaporizer 40 from the flow rate sensor (F) via a wired or wireless.

When the flow rate of the liquefied gas flowing into the vaporizer 40 received from the flow rate sensor F increases, the first control unit drives the pumps 43a to 43c which are variable frequency driven among the intermediate heat medium pumps 43a to 43c. It can be controlled to increase the flow rate, when the flow rate of the liquefied gas flowing into the vaporizer 40 received from the flow rate sensor (F), the variable frequency driven pump 43a ~ of the intermediate heat medium pump (43a ~ 43c) Control to reduce the drive flow rate of 43c).

The second control unit can control the plurality of seawater pumps 44a to 44f in accordance with the temperature of the fruit (sea water) discharged from the seawater heat exchangers 42a to 42c.

At this time, the second control unit may receive the temperature of the fruit (sea water) discharged from the seawater heat exchanger (42a ~ 42c) via a wired or wireless from the third temperature sensor (T3).

Specifically, when the temperature of the fruit discharged from the seawater heat exchangers 42a to 42c increases, the second control unit may control the variable frequency drive (VFD) of the pumps 44a to 44f among the plurality of seawater pumps 44a to 44f. When the flow rate is controlled to reduce the flow rate, and the temperature of the fruit discharged from the seawater heat exchangers 42a to 42c decreases, the pumps 44a to 44f of the variable frequency drive VFD among the plurality of seawater pumps 44a to 44f are reduced. It can be controlled to increase the driving flow rate.

Referring to Figure 5, as in the first embodiment of the present invention power consumption diagram (B) in the case of driving both the intermediate heat medium supply pump (43a ~ 43c) and the sea water pump (44a ~ 44f) variable frequency is a conventional intermediate heat medium It can be seen that both the supply pumps 43a to 43c and the sea water pumps 44a to 44f show lower power consumption diagrams than the power consumption diagram A in the case of a fixed-speed slave pump. .

It can be seen that the regasification system 1 according to the first embodiment of the present invention has less power consumption than the regasification system 2 according to the second embodiment described later.

Specifically, in the regasification system 2 according to the second embodiment, only one intermediate heating medium supply pump 43a and one seawater pump 44a are variable frequency driven, and the power consumption diagram in this case is C. Yes. Accordingly, the power consumption diagram B in the regasification system 1 according to the first embodiment of the present invention is compared with the power consumption diagram C in the regasification system 2 according to the second embodiment. It can be seen that when the low power consumption.

Accordingly, it can be seen that the regasification system 1 according to the first embodiment of the present invention has an effect of significantly reducing the power consumption compared to the conventional regasification system, as well as the overall systems 2 and 3. It can be seen that the lowest power consumption compared to.

As described above, in the embodiment of the present invention, both the intermediate heat medium supply pumps 43a to 43c and the seawater pumps 44a to 44f can be driven at variable frequency, and by controlling the variable frequency driven pump through the first and second control units. Since the flow rate of the intermediate heat medium can be efficiently managed and the flow rate of the sea water can be managed efficiently, the regasification efficiency is increased.

As described above, the regasification system 1 and the ship 100 including the same according to the present invention, to optimally supply the intermediate heat medium to be supplied to the regasification apparatus (40, 41) to supply unnecessary intermediate heat medium It is effective to reduce the energy consumed.

3 is a conceptual diagram of a part of a regasification system according to a second exemplary embodiment of the present invention.

As shown in FIG. 3, the regasification system 2 according to the second embodiment of the present invention includes a suction drum 30, a boosting pump 21, a vaporizer 40, a trim heater 41, and a first heater. Demand destination 61, seawater heat exchanger 42a-42c, intermediate heat medium pump 43a-43c, sea water pump 44a-44f, intermediate heat medium circulation line GL, first to third intermediate heat medium pump lines GL1 GL3), seawater supply line SL, first to third temperature sensors T1 to T3, flow sensor F, first to ninth control valves B1 to B9, and first and second control units Not shown).

In the second embodiment of the present invention, the configurations other than the intermediate heat medium pumps 43a to 43c and the seawater pumps 44a to 44f are the same as those in the first embodiment, so that they are replaced with those described in the first embodiment. Hereinafter, the configuration of the intermediate heat medium pumps 43a to 43c and the sea water pumps 44a to 44f will be described in detail. Here, the seawater heat exchangers 42a to 42c may be referred to as intermediate heat exchanger heat exchangers, and the seawater pumps 44a to 44f may be referred to as heat source supply pumps.

In the second embodiment of the present invention, only one of the intermediate heat medium pumps 43a to 43c and the seawater pumps 44a to 44f may be variable frequency driven, unlike in the first embodiment in which both are variable frequency driven.

For example, in the second embodiment of the present invention, only one intermediate heat medium pump 43a of the plurality of intermediate heat medium pumps 43a to 43c is variable frequency driven, and the remaining intermediate heat medium pumps 43b and 43c are fixed. It may be a fixed-speed slave pump, in which only one seawater pump 44a of the plurality of seawater pumps 44a to 44f is variable frequency driven, and the remaining seawater pumps 44b to 44f are fixed speed. It may be a fixed-speed slave pump.

In this case, the fixed speed dependent pump cannot control the discharged flow rate by itself, but only on-off control, variable frequency driven intermediate heat pump 43a and variable frequency driven seawater pump 44a. Each of the first control valve B1 and the fourth control valve B4 provided downstream may be a control valve, and the fixed speed dependent pump of the plurality of intermediate heat medium pumps 43a to 43c may be provided. Second and third regulating valves B2 and B3 and fifth to ninth provided downstream of the fixed speed dependent pumps 44b to 44f among the fields 43b and 43c and the plurality of seawater pumps 44a to 44f. The control valves B5 to B9 may be remote throttle valves.

In general, variable frequency driven pumps are disadvantageous in that they are expensive and have a lot of space to be built up compared to fixed speed dependent pumps.

Accordingly, in the second embodiment of the present invention, unlike the first embodiment in which all the plurality of intermediate heat medium pumps 43a to 43c and the seawater pumps 44a to 44f are variable frequency driven, the intermediate heat medium pumps 43a to 43c) and only one of the seawater pumps 44a to 44f can be driven with variable frequency, thereby reducing the construction cost and optimizing the construction space.

Furthermore, referring to FIG. 5, as in the second embodiment of the present invention, one of the intermediate heat medium supply pumps 43a to 43c and the sea water pumps 44a to 44f and one seawater pump 44a is provided. The power consumption diagram C when only the variable frequency drive is performed is the power when the conventional intermediate heat supply pumps 43a to 43c and the seawater pumps 44a to 44f are fixed-speed slave pumps. It can be seen that the power consumption diagram is lower than the consumption diagram (A).

Therefore, it can be seen that the regasification system 2 according to the second embodiment of the present invention has an effect of significantly reducing power consumption compared to the conventional regasification system.

In addition, as described above, the regasification system 2 and the ship 100 including the same according to the present invention, by supplying the intermediate heat medium to be supplied to the regasification device (40, 41) optimally to supply unnecessary intermediate heat medium It has the effect of reducing the energy consumed to supply.

4 is a conceptual diagram of a part of a regasification system according to a third exemplary embodiment of the present invention.

As shown in FIG. 4, the regasification system 3 according to the third embodiment of the present invention includes a suction drum 30, a boosting pump 21, a vaporizer 40, a trim heater 41, and a first heater. Demand destination 61, seawater heat exchanger 42a-42c, intermediate heat medium pump 43a-43c, sea water pump 44a-44f, intermediate heat medium circulation line GL, first to third intermediate heat medium pump lines GL1 GL3), seawater supply line SL, first to fourth shared lines BL1 to BL4, first to third temperature sensors T1 to T3, flow sensor F, first to ninth control valves (B1-B9) and 1st-3rd control part (not shown) is included.

In the third embodiment of the present invention, the configurations of the intermediate heat medium pumps 43a to 43c and the seawater pumps 44a to 44f are the same as those of the second embodiment, and the suction drum 30, the boosting pump 21 and the vaporizer ( 40, trim heater 41, first demand source 61, seawater heat exchangers 42a to 42c, intermediate heat medium circulation line GL, seawater supply line SL, first to third temperature sensors T1 to T3), the flow rate sensor F, the first to ninth control valves B1 to B9, and the first and second control units (not shown) are all the same as those of the first embodiment, and thus described in the first embodiment. Replace with one bar.

Hereinafter, the configuration of the third control unit, the first to fourth shared lines BL1 to BL4 and the first to third intermediate thermal medium pump lines GL1 to GL3 will be described in detail. Here, the seawater heat exchangers 42a to 42c may be referred to as intermediate heat exchanger heat exchangers, and the seawater pumps 44a to 44f may be referred to as heat source supply pumps.

Unlike the first and second embodiments, the first to third intermediate heat medium pump lines GL1 to GL3 may be directly connected to each of the first to third trains, rather than being connected to the intermediate heat medium circulation line GL. have.

That is, the first intermediate heat medium pump line GL1 is connected to the third train A2, the second intermediate heat medium pump line GL2 is connected to the second train A1, and the third intermediate heat medium pump line GL3. ) May be connected to the first train.

The first to fourth sharing lines BL1 to BL4 may connect and share the plurality of intermediate thermal medium pump lines GL1 to GL3, respectively. At this time, each of the sharing lines BL1 to BL4 may be provided with a plurality of control valves (not shown) for controlling the flow of the intermediate heat medium.

Here, the plurality of control valves may be connected to the third control unit by wire or wirelessly to receive an opening degree adjustment instruction from the third control unit.

The third control unit may adjust the opening degree of the plurality of control valves when the plurality of intermediate heat medium pumps 43a to 43c are malfunctioning or stopped.

In this case, the third control unit receives the malfunction or stop information of the plurality of intermediate heat medium pumps 43a to 43c from the plurality of intermediate heat medium pumps 43a to 43c via wired or wireless, The dog can be controlled by wireless.

Specifically, when the at least one of the plurality of intermediate heat medium pumps 43a to 43c malfunctions or stops, the third control unit stops the pump that is malfunctioning or stopped among the plurality of intermediate heat medium pumps 43a to 43c, and adjusts the plurality of adjustments. The opening of the at least one control valve of the control valve for supplying the intermediate heat medium to the intermediate heat medium pump line in which the malfunctioning or stopped pump is provided can be controlled. At this time, basically, the plurality of control valves are all opened.

For example, when one of the intermediate heat medium pumps 43a to 43c of the intermediate heat medium pump 43a is malfunctioning or stopped, the third controller may be one of the plurality of intermediate heat medium pumps 43a to 43c that is malfunctioning or stopped. The operation may be controlled to stop the intermediate heat medium pump 43a and to open the opening of the control valve provided on the first sharing line BL1 among the plurality of control valves. In this case, the third control unit may control to open the opening degree of the control valve provided on the third sharing line BL3.

If the malfunctioning or stopped pump among the plurality of intermediate heat medium pumps 43a to 43c is the intermediate heat medium pump 43b, the third control unit stops the malfunctioning or stopped medium heat medium pump 43b and adjusts the plurality of intermediate heat medium pumps 43b. One of the control valves provided on the first sharing line BL1 and the control valve provided on the second sharing line BL2 may be controlled to open the opening degree. Of course, the third controller may control to open both the control valve provided on the first sharing line BL1 and the control valve provided on the second sharing line BL2.

In this case, the third control unit may control to open the opening degree of the control valve provided on the third sharing line BL3 or the opening degree of the control valve provided on the fourth sharing line BL4.

As described above, in the embodiment of the present invention, the intermediate heat medium supply pumps 43a to 43c and the seawater pumps 44a to 44f are controlled by a pump that is malfunctioning or stopped through the third control unit, thereby continuously intermediary to each of the first to third trains. Since the heat medium can be supplied, the system reliability is improved and the regasification efficiency is increased.

In addition, as described above, the regasification system 3 and the vessel 100 including the same according to the present invention, by optimally supplying the intermediate heat medium to be supplied to the regasification apparatus (40, 41) to provide unnecessary intermediate heat medium It has the effect of reducing the energy consumed to supply.

Although the present invention has been described in detail through specific examples, it is intended to describe the present invention in detail, and the present invention is not limited thereto, and should be understood by those skilled in the art within the technical spirit of the present invention. It is obvious that the modifications and improvements are possible.

All simple modifications and variations of the present invention fall within the scope of the present invention, and the specific scope of protection of the present invention will be apparent from the appended claims.

1,2,3: regasification system 10: liquefied gas storage tank
20: Feeding Pump 21: Boosting Pump
30: suction drum 40: carburetor
41: trim heater 42a-42c: seawater heat exchanger
43a to 43c: intermediate heat pump 44a to 44f: seawater pump
B1 to B9: first to ninth control valves 50: boil-off gas compressor
61: first demand source 62: second demand source
100: vessel containing regasification system
L1: liquefied gas supply line L2: regasified gas supply line
L3: boil-off gas supply line GL: intermediate heat medium circulation line
GL1 ~ GL3: First to third intermediate heat medium pump line SL: Sea water supply line
BL1 to BL4: first to fourth sharing lines

Claims (12)

A vaporizer to heat the liquefied gas with an intermediate heat medium to regasify it;
A plurality of intermediate heat medium pumps for supplying the intermediate heat medium;
A plurality of intermediate heat medium heat exchangers for heating the intermediate heat medium; And
A plurality of heat source supply pumps for supplying heat to the plurality of intermediate heat medium heat exchangers,
At least one of the plurality of intermediate heat pumps is variable frequency driven (VFD),
A first control unit controlling a variable frequency driven pump among the plurality of intermediate heat medium pumps according to a temperature of liquefied gas discharged from the vaporizer or a temperature of an intermediate heat medium discharged from the vaporizer;
At least one of the plurality of heat source supply pumps is variable frequency driven,
And a second control unit for controlling a variable frequency driven pump among the plurality of heat source supply pumps according to the temperature of the fruit discharged from the intermediate heat exchanger. The method of claim 1, wherein the plurality of intermediate heat medium pump and the heat source supply pump,
Regasification system, characterized in that all are variable frequency drive (VFD). The method of claim 1, wherein the plurality of intermediate heat medium pump and the plurality of heat source supply pump,
Regasification system, characterized in that only one intermediate heat pump or one heat source supply pump is variable frequency driven (VFD). delete The method of claim 1, wherein the first control unit,
When the temperature of any one of the temperature of the intermediate heat medium discharged from the vaporizer or the temperature of the liquefied gas discharged from the vaporizer increases, controlling to reduce the drive flow rate of the variable frequency drive (VFD) of the plurality of intermediate heat medium pumps and,
When the temperature of any one of the temperature of the intermediate heat medium discharged from the vaporizer or the temperature of the liquefied gas discharged from the vaporizer decreases, the driving flow rate of the variable frequency driven (VFD) pump among the plurality of intermediate heat medium pumps is increased. Regasification system characterized in that. delete The method of claim 1, wherein the second control unit,
When the temperature of the fruit discharged from the intermediate heat exchanger is increased, the flow rate of the variable frequency drive (VFD) of the plurality of heat source supply pump is controlled to reduce the drive flow rate,
And when the temperature of the fruit discharged from the intermediate heat exchanger decreases, increasing the driving flow rate of the variable frequency driven (VFD) pump among the plurality of heat source supply pumps. The method of claim 1,
An intermediate heat medium circulation line configured to circulate the intermediate heat medium to the vaporizer, the plurality of intermediate heat medium pumps, the plurality of intermediate heat medium heat exchangers, and the plurality of heat source supply pumps; And
And a plurality of intermediate heat medium pump lines branched on the intermediate heat medium circulation line, the plurality of intermediate heat medium pump lines respectively formed to include the plurality of intermediate heat medium pumps. The method of claim 8, wherein the plurality of intermediate heat medium pump line,
Regasification system characterized in that connected in parallel with each other. The method of claim 8,
A first train including the first vaporizer when the vaporizer is called a first vaporizer; And
Further comprising a second train including a second vaporizer for vaporizing the liquefied gas by heat exchange with the intermediate heat medium,
The plurality of intermediate heat medium pump line,
A regasification system connected to each of the first train and the second train. The method of claim 10,
A plurality of sharing lines connecting and sharing the plurality of intermediate heat medium pump lines with each other;
A plurality of control valves provided on the plurality of sharing lines to control the flow of the intermediate heat medium; And
Further comprising a third control unit for controlling the opening degree of the plurality of control valve when the malfunction or stop of the plurality of intermediate heat medium pump,
The third control unit,
Intermediate heat medium pump which stops the malfunction or stopped pump among the plurality of intermediate heat medium pumps when at least one of the plurality of intermediate heat medium pumps malfunctions or stops, and the malfunction or stopped pump of the plurality of control valves is provided. And reopen the opening of at least one regulating valve of the regulating valve to supply the intermediate heating medium to the line. A ship comprising the regasification system of any one of claims 1 to 3, 5 and 7 to 11.

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