KR102026539B1 - Hybrid Vessel of LNG Carrier and FSRU - Google Patents

Abstract

Hybrid vessel of the LNG carrier and the FSRU according to an embodiment of the present invention, liquefied gas storage tank; A regasification apparatus for regasifying the liquefied gas stored in the liquefied gas storage tank; A power generation device for supplying power to the regasification device; And an electric propulsion device receiving power from the power generation device to generate propulsion power.

Description

Hybrid Vessel of LNG Carrier and FSRU

The present invention relates to a hybrid vessel of an LNG carrier and an FSRU.

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 lowering the temperature of methane, the main component, below -162 ℃ under 1 atmosphere, and the volume of liquefied methane is about 1/600 of the volume of gaseous methane in the standard state. Is 0.42, which is about one half of 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 LNG regasification system installed on land, natural gas vaporized on land by removing the propulsion system and installing a regasification apparatus on an LNG carrier carrying Liquefied Natural Gas. ) (Eg LNG FSRU) is in the spotlight. Since the FSRU is removed from the propulsion unit, there is a problem in that it cannot be used as a carrier because it does not have a high-speed propulsion unit and needs to stay in only one region.

With the recent diversification of the market for liquefied natural gas and the diversification of its size, it is impossible for the FSRU to stay in one region for a long time. As a result, there is a growing demand for ships that can implement both LNG carriers and FSRUs.

 Therefore, in the present situation, many development of LNG carriers which have the function of FSRU is performed.

SUMMARY OF THE INVENTION The present invention has been made to improve the prior art, and an object of the present invention is to provide a hybrid vessel of an LNG carrier and an FSRU capable of carrying liquefied gas while having a function of regasifying liquefied gas.

Hybrid vessel of the LNG carrier and the FSRU according to an embodiment of the present invention, liquefied gas storage tank; A regasification apparatus for regasifying the liquefied gas stored in the liquefied gas storage tank; A power generation device for supplying power to the regasification device; And an electric propulsion device receiving power from the power generation device to generate propulsion power.

Specifically, the liquefied gas regasification mode in which the regasification apparatus is operated; And a liquefied gas transport mode in which the propulsion power of the electric propulsion device is operated, wherein the power generator includes power consumption of the regasification device consumed in the liquefied gas regasification mode or consumption in the liquefied gas transport mode. It may be greater than the power consumption of the electric propulsion device.

In detail, a plurality of power generating apparatuses may be provided. In the liquefied gas regasification mode and the liquefied gas transport mode, some of the power generating apparatuses may be driven normally, and the remaining power generating engines may be standby.

Specifically, the control unit further includes a control unit for driving at least one of the plurality of power generation apparatuses according to the liquefied gas regasification mode or the liquefied gas transportation mode, wherein the control unit includes the liquefied gas regasification mode and the liquefied gas delivery mode At least one of the generators may be controlled to be standby.

Specifically, four generators are provided, and the control unit drives the three generators in the liquefied gas regasification mode and the liquefied gas transport mode, and controls the other one of the generators in the standby mode. can do.

In detail, the regasification apparatus receives and regasifies the liquefied gas stored in the liquefied gas storage tank, and the power generation apparatus receives the evaporated gas generated from the liquefied gas storage tank and supplies the regasification apparatus or the electric propulsion. It can produce the power required for the device.

Specifically, the regasification apparatus, the buffer tank for receiving the liquefied gas stored in the liquefied gas storage tank for temporary storage; A boosting pump for pressurizing the liquefied gas supplied from the buffer tank; And it may include a vaporizer for receiving the pressurized liquefied gas from the boosting pump to re-gas.

Specifically, the fuel supply apparatus further comprises a fuel supply device for processing the boil-off gas generated in the liquefied gas storage tank and supplying the boil-off gas generated in the liquefied gas storage tank. It may include a boil-off gas compressor to supply to the power generator.

Specifically, the apparatus further includes a power processor for processing power generated by the power generator, wherein the power processor includes: the power generator; And a power divider configured to receive the power generated by the power generator and distribute the power to the regasification device or the electric propulsion device.

Specifically, the electric propulsion device, a motor for generating a rotational force by receiving power from the power distributor; And a propeller connected to the propulsion shaft coupled with the motor to be rotated to receive a rotational force generated from the motor to generate a propulsion force.

Specifically, the power generator may be a large capacity power generation engine that produces 29 to 31 megawatts (MW) of power.

Specifically, the regasifier may be a large capacity regasifier that consumes 17 to 19 megawatts (MW) of power.

The hybrid vessel of the LNG carrier and the FSRU according to the present invention has the functions of both a liquefied gas regasification system and a liquefied gas carrier, and can be flexibly introduced into various markets at any time, thereby greatly improving the market competitiveness of the vessel. It is effective.

1 is a conceptual diagram of a hybrid vessel of an LNG carrier and an FSRU of the present invention.
2 is a conceptual diagram of a gas treatment system of a hybrid vessel of an LNG carrier and an FSRU according to a first embodiment of the present invention.
3 is a conceptual diagram of a gas treatment system of a hybrid vessel of an LNG carrier and an FSRU according to a second 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 as a meaning encompassing all gaseous fuels which are generally stored in a liquid state, such as LNG or LPG, ethylene, ammonia, and the like, and may mean LNG (Liquefied Natural Gas). For example, the liquid may be expressed as a liquefied gas for the sake of convenience. This can be applied to the boil-off gas as well.

In addition, LNG can be used for the purpose of encompassing not only liquid NG (Natural Gas) but also supercritical NG, for convenience, and boil-off gas means BOG (Boil Off Gas), which is naturally vaporized LNG, and gaseous state. It can be used to include not only the boil off gas but also liquefied boil off gas.

Liquefied gas may be referred to regardless of the change of state, such as liquid state, gas state, liquid and gas mixed state, subcooled state, supercritical state, etc., it is also known that evaporated gas is the same. In addition, the present invention is not limited to the liquefied gas to be treated, it may be a liquefied gas treatment system and / or boil-off gas treatment system, it is apparent that the system of each of the drawings to be carried out can be applied to each other.

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 hybrid vessel of an LNG carrier and an FSRU of the present invention.

As shown in FIG. 1, the hybrid vessel 1 of an LNG carrier and an FSRU according to an embodiment of the present invention includes a liquefied gas storage tank 10, regasification apparatuses 20 and 20a, and a power processing apparatus 30. And a fuel processing device 40.

The hybrid vessel 1 of the LNG carrier and the FSRU includes a liquefied gas storage tank 10 and a power processing device 30 inside the hull 1a, and regasification apparatuses 20 and 20a on the hull 1a. It may have a fuel processing device (40). Here, the regasification apparatus (20, 20a), for example, but is provided on the fore side side upper deck, this is only an example and may be disposed in the center of the fore.

In addition, the regasification apparatus 20, 20a may be a large capacity regasification apparatus 20 or a small capacity regasification apparatus 20a according to the organic coupling with the components selected in each embodiment. This will be described in detail in each embodiment.

The LNG carrier and the FSRU hybrid vessel 1 according to the present invention are vessels capable of meeting the needs of the current market in which the market of liquefied natural gas is diversified and the scale is very diversified. It was the first vessel designed to implement both the transport mode) and the FSRU's function (liquefied gas regasification mode).

It will be appreciated by those skilled in the art that such a vessel cannot be implemented by simply combining the individual devices of the FSRU with the individual devices of the LNG Carrier.

In the following, embodiments of the hybrid vessel 1 of the LNG carrier and the FSRU as described above will be described in detail with reference to FIGS. 2 and 3.

2 is a conceptual diagram of a gas treatment system of a hybrid vessel of an LNG carrier and an FSRU according to a first embodiment of the present invention.

As shown in FIG. 2, the gas processing system 2 according to the embodiment of the present invention includes a liquefied gas storage tank 10, a regasification apparatus 20, a power processing apparatus 30, and a fuel processing apparatus 40. ), The demand destination 50, the electric propulsion unit 61 and the control unit (not shown).

Hereinafter, a gas treatment system 2 according to an exemplary embodiment of the present invention will be described with reference to FIG. 2.

Prior to describing the individual configurations of the gas treatment system 2 according to the embodiment of the present invention, basic flow paths for organically connecting the individual components 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 an embodiment of the present invention, the liquefied gas supply line (L1), may further include a boil-off gas fuel supply line (L2). 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 demand destination 50 and passes through the regasification apparatus 20, and receives and processes the liquefied gas from the regasification apparatus 20 to process the demand destination ( 50).

The boil-off gas fuel supply line L2 connects the liquefied gas storage tank 10 and the power generation engine 31 and passes through the fuel processing device 40, and receives and processes the boil-off gas from the fuel processing device 40. Supply to the power generation engine (31).

Hereinafter, individual components which are organically formed by the lines L1 and L2 described above to implement the gas treatment system 2 will be described.

The liquefied gas storage tank 10 stores the liquefied gas to be supplied to the demand destination 50. 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 provided in the interior of the ship 1, it may be formed in the front of the engine room (not shown), for example three or four. 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.

In the present invention may further include a feeding pump (11).

The feeding pump 11 is provided on the liquefied gas supply line L1 and installed inside or outside the liquefied gas storage tank 10 to store liquefied gas stored in the liquefied gas storage tank 10 for the buffer tank 21. Can be supplied by

Specifically, the feeding pump 11 is provided between the liquefied gas storage tank 10 and the buffer tank 21 on the liquefied gas supply line (L1) to primary liquefied gas stored in the liquefied gas storage tank 10 It can be pressurized and supplied to the buffer tank 21.

The feeding pump 11 may pressurize the liquefied gas stored in the liquefied gas storage tank 10 to 6 to 8 bar and supply it to the buffer tank 21. Here, the feeding pump 11 may pressurize the liquefied gas discharged from the liquefied gas storage tank 10 to increase the pressure and temperature, and the pressurized liquefied gas may still be in a liquid state.

In this case, the feeding pump 11 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 11 is installed outside the liquefied gas storage tank 10. It may be provided at a position inside the hull lower than the level of the liquefied gas and may be a centrifugal pump.

The regasification apparatus 20 regasses the liquefied gas stored in the liquefied gas storage tank 10 and is driven by receiving electric power from the power generator 31.

Specifically, the regasification apparatus 20 includes a buffer tank 21, a boosting pump 22, and a vaporizer 23, and liquefied gas stored in the liquefied gas storage tank 10 through the liquefied gas supply line L1. Receiving is supplied to the regasification process can be supplied to the demand destination (50).

In addition, the regasifier 20 may be a large capacity regasifier that consumes 17 to 19 megawatts (MW) of power, and the power divider 32 and the regenerator to drive such a regasifier 20. Power may be supplied through the fire power supply line (EL2), the power generation capacity of the power generation engine 31 of the power supply device 30 can be designed and driven accordingly, which will be described later.

The buffer tank 21 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.

Specifically, the buffer tank 21 may be supplied with the liquefied gas stored in the liquefied gas storage tank 10 from the feeding pump 11 through the liquefied gas supply line (L1), by temporarily storing the supplied liquefied gas 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 22.

That is, the buffer tank 21 temporarily stores the liquefied gas to separate the liquid phase and the gaseous phase, so that the complete liquid phase is supplied to the boosting pump 22 so that the boosting pump 22 satisfies the effective suction head NPSH. And, it is thereby possible to prevent the cavitation (Cavitation) in the boosting pump (22).

Boosting pump 22 may be provided between the buffer tank 21 and the vaporizer 23 on the liquefied gas supply line (L1), from the liquefied gas or buffer tank 21 supplied from the feeding pump 11 The supplied liquefied gas may be pressurized to 80 to 120 bar and supplied to the vaporizer 23.

The boosting pump 22 may pressurize the liquefied gas according to the pressure required by the customer 50, and may be configured as a centrifugal pump.

The vaporizer 23 may be connected to the liquefied gas supply line L1 to regasify the high pressure liquefied gas discharged from the boosting pump 22, and then supply the liquefied gas to the demand destination 50.

The power processor 30 may process power generated by the power generation engine 31.

Specifically, the power processing device 30 generates power required for the regasification device 20 and the electric propulsion device 61 to supply power to the regasification device 20 and the electric propulsion device 61, and generates electricity. Engine 31 and power divider 32.

Here, the power processing device 30 may have power lines for supplying power or distributing power generated in each component to other components, and the power lines include a power generation engine power supply line EL1 and a regasification device power. It may include a supply line (EL2), electric propulsion device power supply line (EL3).

The power generation engine 31 supplies electric power for the regasification device 20 and the electric propulsion device 61.

The power generation engine 31 may be larger than the power consumption of the regasification apparatus 20 consumed in the liquefied gas regasification mode or the power consumption of the electric propulsion apparatus 61 consumed in the liquefied gas transport mode, and may be 29 to 31 megagrams. It could be a large capacity power generation engine that produces watts (MW) of power.

The power generation engine 31 is provided with a plurality (preferably provided with four) in the liquefied gas regasification mode and the liquefied gas transport mode, part of the normal operation and the rest can be standby, this drive is the Can be implemented by control. Detailed driving control will be described later in the controller.

The power divider 32 may receive the power generated by the power generation engine 31 and distribute the power to the regasification device 20 or the electric propulsion device 61.

Specifically, the power divider 32 is connected to the four power generation engine 31 and the power generation engine power supply line EL1, respectively, to receive the power generated by the generator G of the power generation engine 31, and recover Connected to the fire extinguishing device 20 and the regasification device power supply line EL2, and connected to the electric propulsion device 61 and the electric propulsion device power supply line EL3 to regasify the power received from the power generation engine 31, respectively. It may be supplied to the device 20 or the electric propulsion device (61).

The fuel processing device 40 may process and supply the boil-off gas generated in the liquefied gas storage tank 10 to the power generation engine 31, and may further include an boil-off gas compressor 41.

The boil-off gas compressor 41 receives and compresses the boil-off gas generated from the liquefied gas storage tank 10 through the boil-off gas fuel supply line L2 and compresses the boil-off gas through the boil-off gas fuel supply line L2. Can be supplied by

The demand destination 50 may receive and consume the liquefied gas regasified by the regasification device 20, and may be, for example, a land demand destination, but is not limited thereto.

The electric propulsion device 61 receives electric power from the power generator 31 to generate propulsion power.

The electric propulsion device 61 may be a motor 61 and may receive power from the electric power distributor 32 through the electric propulsion device power supply line EL3 to generate a rotational force.

The electric propulsion device 61 may further include a propeller P receiving a rotational force to the propulsion shaft S geared with the motor 61.

The propeller P is connected to the propulsion shaft S which is gear-coupled with the motor 61, and is rotated by receiving the rotational force generated from the motor 61 to generate a propulsion force in the vessel 1.

The present invention, which is expressed by the organic combination of the above configurations, may have a liquefied gas regasification mode in which the regasification apparatus 20 is operated, and a liquefied gas transport mode in which the driving force of the electric propulsion apparatus 61 is operated. have.

As described above, the vessel 1 of the present invention may implement the liquefied gas regasification mode and the liquefied gas transport mode through a control unit.

The controller may standbyly drive at least one of the plurality of power generation engines 31 according to the liquefied gas regasification mode or the liquefied gas transport mode.

In detail, the controller may control at least one of the power generation engine 31 to be standby in the liquefied gas regasification mode and the liquefied gas transport mode.

That is, the controller may drive three power generation engines 31 in the liquefied gas regasification mode and the liquefied gas transport mode, and control the remaining one power generation engine 31 in the standby mode.

As described above, the present invention is to design the power consumption capacity of the regasification device 20 and the power generation capacity of the power supply device 30 for supply and demand of power, and to control it by the control unit; At the same time, the propulsion device 61 is optimally designed to have the functions of both a liquefied gas regasification system and a liquefied gas carrier.

Through this, the ship 1 of the present invention can be flexibly introduced into various markets at any time, and thus, the market competitiveness of the ship 1 is extremely improved.

3 is a conceptual diagram of a gas treatment system of a hybrid vessel of an LNG carrier and an FSRU according to a second embodiment of the present invention.

As shown in FIG. 3, the gas processing system 2 according to the second embodiment of the present invention includes a liquefied gas storage tank 10, regasification apparatuses 20 and 20a, a power processing apparatus 30, and a fuel. It includes a processing apparatus 40, a demand destination 50, a large engine 62, and a control unit (not shown).

Here, the gas treatment system 2 according to the second embodiment of the present invention differs from the gas treatment system 2 according to the first embodiment in the propulsion method and the power generation method, and is recovered due to the difference between the propulsion method and the power generation method. There is a change in the power consumption capacity of the fire extinguishing device (large capacity regasification device 20 and small capacity regasification device 20a).

Therefore, the gas processing system 2 according to the second embodiment of the present invention, unlike the gas processing system 2 according to the first embodiment, changes in the structure of the power processing device 30 and the fuel processing device 40. There is a large engine 62 is further arranged, the control configuration of the control unit according to this change and additional arrangement has been changed. Details thereof will be described later.

Therefore, in the gas processing system 2 according to the second embodiment of the present invention, the configuration of the power processing device 30, the fuel processing device 40, the large engine 62, and the control unit is other than the gas processing according to the first embodiment. The same reference numerals may be used for convenience of each configuration in the system 2, but do not necessarily refer to the same configuration.

Hereinafter, a gas treatment system 2 according to a second embodiment of the present invention will be described with reference to FIG. 3.

Prior to describing the individual configurations of the gas treatment system 2 according to the embodiment of the present invention, basic flow paths for organically connecting the individual components 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, the liquefied gas supply line (L1), evaporative gas fuel supply line (L2), liquefied gas fuel supply line (L3), power generation engine fuel supply line (L4) and minimum send-out line (L5) It may further include. 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 demand destination 50 and receives liquefied gas from the regasification apparatus 20, 20a via the regasification apparatus 20, 20a. Processing to be supplied to the demand destination (50).

The boil-off gas fuel supply line L2 connects the liquefied gas storage tank 10 and the large engine 62 and passes through the fuel processing device 40, and is provided in the boil-off gas compressor 41 of the fuel processing device 40. The boil-off gas is supplied and processed to be supplied to the large engine 62.

The liquefied gas fuel supply line L3 connects the liquefied gas storage tank 10 and the large engine 62 and passes through the fuel processing device 40, the fuel pump 42 of the fuel processing device 40, and The liquefied gas is supplied from the fuel vaporizer 43 and processed to be supplied to the large engine 62.

The power generation engine fuel supply line L4 is branched from an intermediate stage (between the second and third stages) of the boil-off gas compressor 41 on the boil-off gas fuel supply line L2 to connect the power generation engine 31 to the boil-off gas compressor. Receiving the boil-off gas at 41 and compresses to low pressure to be supplied to the power generation engine (31).

The minimum send out line L5 is branched from an intermediate stage (between the fourth and fifth stages) of the boil-off gas compressor 41 on the boil-off gas fuel supply line L2 to connect the demand destination 50 to the boil-off gas compressor 41. ) To receive the boil-off gas and compress it to the pressure required by the demand source 50 so as to be supplied to the demand source 50.

Hereinafter, individual components that are organically formed by the lines L1 to L5 described above to implement the gas treatment system 2 will be described.

The regasification apparatuses 20 and 20a regasify the liquefied gas stored in the liquefied gas storage tank 10 and are driven by receiving electric power from the power generation engine 31 or the shaft generator 33.

The regasification apparatus 20.20a includes a buffer tank 21, a boosting pump 22, and a vaporizer 23, and stores the liquefied gas stored in the liquefied gas storage tank 10 through the liquefied gas supply line L1. The supply may be supplied to the demand source 50 by regasification. The regasification treatment mechanism through the above described buffer tank 21, boosting pump 22 and vaporizer 23 has been described above in the gas treatment system 2 according to the first embodiment of the present invention and replaced therewith. .

Regasifiers 20 and 20a are large capacity regasifiers 20 to 17 to 19 megawatts (MW) or small capacity regenerators to consume 9 to 11 megawatts (MW) of power. It may be a gasifier 20a, and the electric power may be supplied through the power distributor 32 and the regasifier power supply line EL2 to drive the regasifier 20,20a. The power generation capacity of the power generation engine 31 of 30 may be designed accordingly or driven by supply and demand of power through generation of the shaft generator 33, which will be described later.

The power processor 30 may process the power generated by the power generation engine 31 and the power generated by the shaft generator 33.

Specifically, the power processing device 30 generates power required for the regasification apparatuses 20 and 20a to supply power to the regasification apparatuses 20 and 20a, and the power generation engine 31 and the power distributor 32. And a shaft generator 33.

Here, the power processing device 30 may have power lines for supplying power or distributing power generated in each component to other components, and the power lines include a power generation engine power supply line EL1 and a regasification device power. It may include a supply line (EL2), the shaft generator power supply line (EL4).

The power generation engine 31 supplies power required for the regasification apparatuses 20 and 20a and the large engine 62, and the total amount of power that can be generated when the regasification apparatus 20 has a large capacity is the regasification apparatus 20. Less than the power consumption of the regasification unit 20a is a small capacity, the total amount of power that can be generated is greater than the power consumption of the regasification unit 20a, the generation of small capacity to produce 11 to 13 megawatts (MW) of power It can be an engine.

The power generation engine 31 is provided with a plurality (preferably provided with four) in the liquefied gas regasification mode and the liquefied gas transport mode, part of the normal operation and the rest can be standby, this drive is the Can be implemented by control. Detailed driving control will be described later in the controller.

The power divider 32 may receive power generated by the power generation engine 31 and the shaft generator 33 and distribute the generated power to the regasification devices 20 and 20a. Of course, the power divider 32 may supply power to some large engines 62.

Specifically, the power divider 32 is connected to the four power generation engine 31 and the power generation engine power supply line (EL1), respectively, can receive the power generated by the generator (G) of the power generation engine 31, 2 Two shaft generators 33 and a shaft generator power supply line EL4, respectively, to receive power generated from the shaft generator 33, and the regasification apparatuses 20 and 20a and the regasification apparatus power supply lines ( EL2) may be supplied to the regasification apparatus (20, 20a) supplied power from the power generation engine 31 and the shaft generator (33).

The shaft generator 33 generates power using the output of the large engine 62 and may be provided on the propulsion shaft S directly connecting the large engine 62 and the propeller P. In this case, a plurality of shaft generators 33 may be provided, and two shaft generators may be provided.

The shaft generator 33 may have a total amount of power that can be generated may be equal to or greater than the power consumption of the large capacity regasifier 20, and may generate 17 to 19 megawatts (MW) of power, and the shaft generator 33 The power generated at) may be supplied to the power divider 32 by the shaft generator power supply line EL4.

The fuel processing apparatus 40 may process the liquefied gas generated in the liquefied gas storage tank 10 or the liquefied gas stored in the liquefied gas storage tank 10 and supply the same to the power generation engine 31 or the large engine 62. In addition, the boil-off gas compressor 41, the fuel pump 42 and the fuel vaporizer 43 may be further included.

The boil-off gas compressor 41 receives and compresses the boil-off gas generated from the liquefied gas storage tank 10 through the boil-off gas fuel supply line L2 and compresses the large-scale engine 62 through the boil-off gas fuel supply line L2. Supply to the power generation engine 31 through the power generation engine fuel supply line (L4), it can be supplied to the demand destination 50 of the regasification apparatus (20, 20a) through the minimum send out line (L5).

The boil-off gas compressor 41 is composed of multiple stages and may be composed of five stages. In this case, the boil-off gas branched between the second stage and the third stage is supplied to the power generation engine 31 and branched between the fourth stage and the fifth stage. The evaporated gas may be supplied to the demand destination 50 of the regasification apparatuses 20 and 20a and the evaporated gas discharged from the final stage may be supplied to the large engine 62.

Here, when the boil-off gas compressor 41 supplies the boil-off gas branched between the fourth stage and the fifth stage to the demand destination 50 of the regasification apparatus 20, 20a, the regasification apparatus 20 in the liquefied gas regasification mode. When 20a) is shut down or when it is necessary to supply the reclaimed liquefied gas with a minimum required flow rate to the demand source 50.

The boil-off gas compressor 41 is provided on the boil-off gas fuel supply line L2, and is provided in plural to pressurize the boil-off gas generated from the liquefied gas storage tank 10 in multiple stages. The boil-off gas compressor 41 may pressurize the boil-off gas generated in the liquefied gas storage tank 10 and discharged at a pressure of about 1 bar to 200 bar to 400 bar (preferably 300 bar) to supply the large engine 62.

In this case, when the multi-stage compression is made of 200 bar to 400 bar (preferably 300 bar), the liquefied gas large engine 62 may be supplied, and the multi-stage compression may be, for example, compressed in two to three stages and thus, 1 to 10 bar (preferably 6 bar) is supplied to the power generation engine 31 and is compressed to about 4 to 5 stages, and if it is composed of 100 to 110 bar (preferably 105 bar), the demand destination 50 of the regasification apparatus (20, 20a) Can be supplied.

 The boil-off gas compressor 41 may adjust the pressure according to the large engine 62 when the large stroke engine is a low-pressure gas injection engine (XDF) using a 2-stroke DF engine, and in this case, the regasification apparatus through the minimum send out line (L5). The function of supplying to the demand destination 50 of 20 and 20a may further include a separate boil-off gas compressor.

An evaporative gas cooler (not shown) may be provided between the plurality of evaporative gas compressors 41. When the boil-off gas is pressurized by the boil-off gas compressor 41, since the temperature may also increase as the pressure increases, the present embodiment may lower the temperature of the boil-off gas using the boil-off gas cooler. The boil-off gas cooler may be installed in the same number as the boil-off gas compressor 41, and each boil-off gas cooler may be provided downstream of each boil-off gas compressor 41.

The fuel pump 42 may pressurize the liquefied gas stored in the liquefied gas storage tank 10, and may supply the pressurized liquefied gas to the fuel vaporizer 43.

Specifically, the fuel pump 42 is provided upstream of the fuel vaporizer 43 on the liquefied gas fuel supply line L3 to supply the liquefied gas supplied from the feeding pump 11 to the pressure required by the large engine 62 ( For example, it may be pressurized to 300 bar and supplied to the fuel vaporizer 43. In addition, the fuel pump 42 may pressurize accordingly when the large engine 62 is a low pressure gas injection engine (XDF) with a two stroke DF engine. Can be adjusted.

The fuel vaporizer 43 can vaporize the liquefied gas pressurized by the fuel pump 42 and supply it to the large engine 62.

Specifically, the fuel vaporizer 43 is provided between the fuel pump 42 on the liquefied gas fuel supply line L3 and the large engine 62 to vaporize the high pressure liquefied gas supplied from the fuel pump 42. At the same time, the large engine 62 can be heated to a temperature required (for example, 45 degrees) and supplied to the large engine 62.

The large engine 62 receives fuel from the liquefied gas storage tank 10 to rotate the propeller P.

Specifically, the large engine 62 is directly connected to the propulsion shaft S provided with the shaft generator 33 and connected to the propeller P, and is a high pressure gas injection engine (MEGI) consuming a pressure of 200 to 400 bar. Can be.

Alternatively, the large engine 62 may be a low pressure gas injection engine (XDF) with a two stroke DF engine.

In the large engine 62, as a piston (not shown) inside a cylinder (not shown) reciprocates by combustion of liquefied gas or evaporated gas, a crank shaft (not shown) connected to the piston is rotated, The propulsion shaft S connected to the crank shaft may be rotated. Therefore, as the propeller P connected to the propulsion shaft S rotates when the large engine 62 is driven, the hull 1a may move forward or backward.

The present invention expressed by the organic combination of the above configuration, the liquefied gas regasification mode in which the regasification apparatus (20, 20a) is operated and the liquefied gas conveyance propeller (P) is operated by the large engine 62 May have a mode.

As described above, the vessel 1 of the present invention may implement the liquefied gas regasification mode and the liquefied gas transport mode through a control unit.

However, the ship 1 of the present invention includes the power supply of the shaft generator 33 and the embodiment of the ship (Example 2-1) and the shaft generator 33 having a large capacity with the regasification device 20. It is possible to have an embodiment of the ship (Example 2-2) having a small capacity of the regasification apparatus 20a without power supply. Of course, in this case, unlike in the first embodiment, the propulsion method has a large engine 61 directly connected through the propeller P and the propulsion shaft S, and the power generation method is a small capacity power generation engine.

Hereinafter, the second embodiment will be described.

In the embodiment 2-1 of the present invention, the plurality of power generation engines 31 are all standby in the liquefied gas regasification mode, but the shaft generator 33 is normally driven, and a part of the power generation engines 31 in the liquefied gas transport mode. ) Is normally driven and the remaining power generation engine 31 is standby, the shaft generator 33 may be normally driven.

In the second embodiment of the present invention, the driving unit 31 may have a control unit for controlling the power generation engine 31 and the shaft generator 33.

The controller may standbyly drive at least one of the plurality of power generation engines 31 according to the liquefied gas regasification mode or the liquefied gas transport mode.

In detail, the controller may control the standby driving of at least one of the plurality of power generation engines 31 in the liquefied gas regasification mode, and control the standby power of all of the power generation engines 31 in the liquefied gas transport mode.

In addition, the controller may control to operate all of the plurality of shaft generators 33 in the liquefied gas regasification mode, and may control at least one of the plurality of shaft generators 33 in the liquefied gas transport mode.

The control configuration of the control unit will be described below by limiting the control in the liquefied gas transport mode to the case where four power generation engines 31 and two shaft generators 33 are provided.

If the vessel 1 of the present invention sails the ocean in the liquefied gas transport mode, the control unit controls one driving of the power generation engine 31 and the remaining three power generation engines 31 to be operated in the standby mode or the shaft Only one generator 33 is controlled to be driven.

When the vessel 1 of the present invention loads or unloads liquefied gas offshore in the liquefied gas transportation mode, the controller drives three power generation engines 31 and controls the remaining one power generation engine 31 in a standby mode. Or both shaft generators 33 are operated.

Accordingly, in the embodiment 2-1 of the present invention, even if the regasification apparatus 20 is provided with a large capacity through the power supply of the power generation engine 31 and the shaft generator 33, the driving of the regasification apparatus 20 is At the same time, since the large engine 62 can be driven at the same time, there is an effect that can also serve as a highly efficient transport function.

Hereinafter, the second embodiment will be described.

In embodiment 2-2 of the present invention, in the liquefied gas regasification mode, all of the plurality of power generation engines 31 are normally driven, and in the liquefied gas transport mode, some power generation engines 31 are normally driven and the remaining power generation engines ( 31) may be standby.

In order to accomplish this driving, in the second embodiment of the present invention, a control unit for controlling the power generation engine 31 may be provided.

The controller may standbyly drive at least one of the plurality of power generation engines 31 according to the liquefied gas regasification mode or the liquefied gas transport mode.

In detail, the controller may control the standby operation of at least one of the plurality of power generation engines 31 in the liquefied gas regasification mode, and control the power generation engines 31 to operate in the liquefied gas transport mode.

The control configuration of the control unit will be described below by limiting the control in the liquefied gas transport mode to the case where four power generation engines 31 are provided.

If the vessel 1 of the present invention sails the ocean in the liquefied gas transport mode, the control unit controls one driving of the power generation engine 31 and the remaining three power generation engines 31 to be operated in the standby mode or the shaft Only one generator 33 is controlled to be driven.

When the vessel 1 of the present invention loads or unloads liquefied gas offshore in the liquefied gas transportation mode, the controller drives three power generation engines 31 and controls the remaining one power generation engine 31 in a standby mode. do.

Accordingly, in the second embodiment of the present invention, the power supply engine 31 has a small capacity, so that the power supply is reduced, so that the regasification device 20a is provided with a small capacity. 20a) can be enabled, and at the same time, it is also possible to drive the large engine 62, which has the effect of serving as a highly efficient transport function.

As described above, the present invention designs the power consumption capacity of the regasification apparatus 20 and 20a and the power generation capacity of the power supply device 30 for supply and demand of power, and is controlled by the controller. At the same time, the propulsion device 62 is optimally designed to have the functions of both a liquefied gas regasification system and a liquefied gas carrier.

Through this, the ship 1 of the present invention can be flexibly introduced into various markets at any time, and thus, the market competitiveness of the ship 1 is extremely improved.

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: Ship 1a: Hull
2: gas treatment system 10: liquefied gas storage tank
11: feeding pump 20,20a: regasifier
21: buffer tank 22: boosting pump
23: carburetor 30: power processing unit
31: power generation engine 32: power distributor
33: shaft generator 40: fuel supply device
41: boil-off compressor 42: fuel pump
43: fuel vaporizer 50: demand source
61: electric propulsion device 62: large engine
L1: liquefied gas supply line L2: boil-off gas fuel supply line
L3: liquefied gas fuel supply line L4: power generation engine fuel supply line
L5: Minimum send out line EL1: Power generation line
EL2: Regasification Power Supply Line EL3: Electric Propulsion Power Supply Line
EL4: power supply line for shaft generator
P: Propeller
S: propulsion shaft

Claims (12)

Liquefied gas storage tanks;
A plurality of power generation engines generating power by receiving fuel from the liquefied gas storage tank;
An electric propulsion device receiving power from the power generation engine to generate propulsion power;
Re-gasification device for receiving power from the power generation engine to regas the liquefied gas stored in the liquefied gas storage tank,
It does not include a propulsion engine connected to the propeller and a shaft generator for generating power from the propulsion engine,
Has a liquefied gas transport mode functioning as an LNG carrier or a liquefied gas regasification mode functioning as an FSRU,
LNG carrier and FSRU hybrid vessel characterized in that the liquefied gas transport mode and liquefied gas regasification mode is selectively implemented without changing the number of operation of the plurality of power generation engines. The method of claim 1, wherein the plurality of power engines,
The hybrid vessel of the LNG carrier and the FSRU, characterized in that the power consumption of the regasification device consumed in the liquefied gas regasification mode or the power consumption of the electric propulsion device consumed in the liquefied gas transport mode. The method of claim 2, wherein the plurality of power generation engine,
In the liquefied gas regasification mode and the liquefied gas conveyance mode, a portion of the LNG carrier and the FSRU hybrid vessel, characterized in that the normal operation and the rest are standby. The method of claim 3, wherein
And a controller configured to standby at least one of the plurality of power generation engines according to the liquefied gas regasification mode or the liquefied gas transport mode.
The control unit,
The hybrid vessel of the LNG carrier and the FSRU characterized in that during the liquefied gas regasification mode and the liquefied gas transport mode, at least one of the plurality of power generation engine is controlled to standby. The method of claim 4, wherein
The power generation engine is provided with four,
The control unit,
In the liquefied gas regasification mode and the liquefied gas conveyance mode, the hybrid carrier of the LNG carrier and the FSRU characterized in that to drive the three power generation engines and to control the remaining one of the power generation engines in a standby mode. The method of claim 1,
The power generation engine, the LNG carrier and the FSRU hybrid vessel, characterized in that for receiving the evaporated gas generated in the liquefied gas storage tank to produce the power required for the regasification device or the electric propulsion device. The method of claim 6, wherein the regasification device,
A buffer tank configured to temporarily receive the liquefied gas stored in the liquefied gas storage tank;
A boosting pump for pressurizing the liquefied gas supplied from the buffer tank; And
LNG carrier and FSRU hybrid vessel comprising a vaporizer for receiving the pressurized liquefied gas from the boosting pump to regasify. The method of claim 7, wherein
Further comprising a fuel supply device for processing the boil-off gas generated in the liquefied gas storage tank to supply to the power generation engine,
The fuel supply device,
LNG carriers and FSRU hybrid vessel comprising a boil-off gas compressor for receiving and compressing the boil-off gas generated in the liquefied gas storage tank to supply to the power generation engine. The method of claim 8,
Further comprising a power processing device for processing power generated by the power generation engine,
The power processing device,
And a power distributor for receiving electric power generated by the power generation engine and distributing it to the regasification device or the electric propulsion device. The method of claim 9, wherein the electric propulsion device,
A motor that receives electric power from the power distributor and generates a rotational force; And
The propeller shaft coupled to the motor gear is coupled to the hybrid ship of the LNG carrier and FSRU further comprising the propeller is rotated by receiving a rotational force generated from the motor to generate a propulsion force. The method of claim 1, wherein the plurality of power engines,
Hybrid vessel of LNG carrier and FSRU, characterized by large capacity producing 29 to 31 megawatts (MW) of power. The method of claim 1, wherein the regasification device,
Hybrid vessel of LNG carrier and FSRU, characterized by large capacity consuming 17 to 19 megawatts (MW) of power.

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