KR20130057796A - Offshore platform for supplying liquefied fuel - Google Patents

Abstract

PURPOSE: An ocean platform for supplying liquefied fuel gas is provided to eliminate the need to move to a fuel supply facility for a vessel and to install the ocean platform for supplying the liquefied fuel gas to a main sailing route and in a sea area. CONSTITUTION: An ocean platform for supplying liquefied fuel gas comprises a liquefied fuel gas storage tank(31), a supply oil pipe(32), a collecting pipe(34), a supply device, and a purging device(40). The supply oil pipe supplies the liquefied fuel gas of the storage tank to a vessel. The collecting pipe collects gas inside a fuel tank to the storage tank. The supply device supplies the liquefied fuel gas to the fuel tank. The purging device removes one or more impurities among the supply oil pipe, the collecting pipe, and a gas propulsion vessel. [Reference numerals] (21) Fuel tank; (31) Storage tank; (33) Pump; (41) Gas supply unit; (60) Liquefying device

Description

Offshore platform for supplying liquefied fuel

The present invention relates to a marine platform for liquefied fuel gas lubrication, and more particularly to a marine platform for liquefied fuel gas lubrication for supplying liquefied fuel gas to ships and the like.

Generally, propulsion engines using petroleum as a fuel were mainly used for ships, but recently, interest in ships using eco-friendly fuels other than petroleum is rapidly increasing due to rising oil prices and tightening environmental regulations.

For example, various types of ships using liquefied natural gas (Liquified Natural Gas, LNG), environmentally friendly liquefied fuel gas such as LPG and DME are expected to be developed.

A new refueling system is needed to supply liquefied fuel gas in line with the development of such new fuel vessels, but until now, the development of vessels using liquefied fuel gas has been mainly focused on supplying liquefied fuel gas to vessels. The development of facilities and facilities to do so was insufficient.

In addition, the current liquefied fuel gas refueling facility is located at a distance from the port for safety and environmental reasons. In order to refuel the vessel, the vessel is liquefied by operating the liquefied fuel gas refueling facility far from the port. It operates a small refueling ship supplied with fuel gas or liquefied fuel gas from an onshore liquefied fuel gas refueling facility to supply liquefied fuel gas to an offshore liquefied fuel gas propulsion vessel.

The above lubrication methods should be provided with liquefied fuel gas fueling facilities on land, but there is a problem that it is not easy to select a suitable site for liquefied fuel gas fueling facilities on land due to the conditions of ship's arrival and the nimbi phenomenon of residents.

Embodiments of the present invention provide a marine platform for liquefied fuel gas refueling that can supply liquefied fuel gas to a ship, a floating structure directly to the sea, without providing a refueling facility on land.

According to an aspect of the present invention, the liquefied fuel gas refueling offshore platform includes a liquefied fuel gas storage tank, a lubrication pipe for lubricating liquefied fuel gas of the storage tank to the ship, and the gas in the fuel tank of the vessel At least one impurity of at least one of a recovery pipe for recovering the tank, a supply device for supplying the liquefied fuel gas of the storage tank to the fuel tank, and the fuel supply pipe, the recovery pipe, and a fuel tank of the gas propulsion vessel. It may include a purging device for removal.

The vessel may further include a connector including a connector for connecting the oil supply pipe and the recovery pipe, the arm receiving the oil supply pipe and the recovery pipe and being coupled to the fuel tank.

A control unit for adjusting the arm, a control unit for receiving a signal of the control unit, and a driving unit for controlling the arm according to the signal of the control unit.

The apparatus may further include a liquefaction device for liquefying the gas recovered to the storage tank or reliquefying the evaporated gas generated in the storage tank to return to the storage tank.

The supply device may include a pump accommodated in the storage tank to pump the liquefied fuel gas.

The supply device includes a vaporization device for vaporizing the liquefied fuel gas of the storage tank, the liquefied fuel gas of the storage tank may be refueled to the fuel tank by the pressure of the gas vaporized by the vaporization device.

Embodiments of the present invention do not need to provide a separate refueling facility on land by providing a marine platform for liquefied fuel gas refueling on the sea and using the same to refuel the vessel.

In addition, by installing the offshore platform for liquefied fuel gas refueling in the sea area close to the main operation route of the vessel can eliminate the inconvenience of having to move to the onshore oil supply facilities for the refueling of the vessel.

In addition, by providing a purging device on the offshore platform for liquefied fuel gas supply, there is no need to install a separate purging device on the ship can reduce the construction cost and maintenance cost of the ship.

1 is a view showing a marine platform for liquefied fuel gas refueling according to an embodiment.
2 is a system diagram illustrating a liquefied fuel gas oil supply system according to an embodiment.
Figure 3 is a schematic diagram showing the operation of refueling the offshore platform for liquefied fuel gas oil supply according to an embodiment.
Figure 4 is a schematic diagram showing the purging operation of the offshore platform for liquefied fuel gas supply according to an embodiment.
5 is a system diagram showing a liquefied fuel gas oil supply system according to another embodiment.
6 is a system diagram showing a liquefied fuel gas oil supply system according to another embodiment.

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

1 is a view showing a marine platform for liquefied fuel gas refueling according to an embodiment, Figure 2 is a system diagram showing a liquefied fuel gas refueling system according to an embodiment, Figure 3 is a liquefied fuel gas according to an embodiment It is a schematic diagram which shows the oil supply operation of the oil supply offshore platform.

In one embodiment, by providing the offshore platform 10 for refueling liquefied fuel gas to supply fuel to the liquefied fuel gas gas propulsion vessel 20 directly from the sea without the need for a land storage facility for storing liquefied fuel gas Suggest a method.

 Here, the liquefied fuel gas refers to a fuel gas liquefied and stored, such as LNG, LPG, DME, LNG, LPG, DME is an example of various types of liquefied fuel gas, the liquefied fuel gas of the present embodiment is not limited thereto.

LNG, or Liquefied Natural Gas, is a cooling liquefaction of methane obtained by purifying natural gas. Natural gas is liquefied by compressing about 600 times in the state of minus 162 degrees. It is a clean fuel that helps to prevent air pollution due to the high content of pure methane, no moisture content and low sulfur content through purification process.

LPG, or liquefied petroleum gas, is a liquid fuel made by compressing a gas mainly composed of propane and butane, which come with petroleum from an oil field, at room temperature. It is easy to liquefy and vaporize, and when liquefied, the volume is reduced to approximately 1/250 for easy storage and transportation.

DME, or dimethyl ether, is a compound extracted from syngas produced by pyrolysis of natural gas, coal, and biomass. It is a kind of ether, which has lower flammability and nontoxic than LPG, and high oxygen content, so it generates less soot during combustion, so it has less environmental load.

Hereinafter, LNG-propelled vessels (hereinafter referred to as 'ships') using LNG as liquefied fuel gas, and LNG bunkering offshore platform (LNG) for refueling liquefied natural gas (LNG) on ships at sea, Hereinafter referred to as 'the offshore platform').

The vessel 20 may be a cargo ship for transporting a large amount of cargo, a dry cargo ship for transporting resources or cargo or a tanker for transporting liquid cargo other than petroleum or petroleum, that is, LPG, LNG, etc. tankers) and many other types of merchant ships.

The offshore platform 10 may be considered a suitable method, such as fixed, semi-submersible, floating, depending on the depth of the offshore platform 10, this embodiment will be described as a fixed type as shown in FIG. The stationary offshore platform 10 allows to maintain the position of the offshore platform 10 by fixing the platform on the sea floor. When the semi-submersible, floating offshore platform is applied, the general position maintaining method applied to the conventional offshore structure may be applied to maintain the position of the platform.

As shown in FIG. 2, the offshore platform 10 removes impurities such as an oil supply system 30 for supplying liquefied fuel gas to the fuel tank 21 of the vessel 20, and a fuel tank 21 of the vessel 20. It may include a purging device 40 for.

Refueling system 30 is installed on the offshore platform 10, the storage tank 31 for storing the liquefied fuel gas, and the oil supply pipe 32 for supplying the liquefied fuel gas to the fuel tank 21 of the vessel 20 And a supply device for providing a forcing force to flow the liquefied fuel gas of the storage tank 31 to the fuel tank 21 of the vessel 20, and a gas in the fuel tank 21 of the vessel 20. 31 may include a recovery pipe 34 for recovery.

The LNG liquefaction temperature is a cryogenic temperature of minus 163 degrees at normal pressure, and because the temperature is only slightly higher than this evaporation, the storage tank 31 and the oil supply pipe 32 is insulated so that it can have a high thermal insulation effect.

The supply device is to provide a pressure for supplying the liquefied fuel gas in the storage tank 31 to the fuel tank 21 of the vessel 20, in one embodiment, a pump 33 may be used.

Recovery pipe 34 is for recovering the pressure build-up gas for maintaining the pressure in the fuel tank 21 of the vessel 20, in order to supply the liquefied fuel gas to the fuel tank 21 It is necessary to remove the pressure building gas in the fuel tank 21 to lower the pressure therein. Therefore, the present embodiment includes a recovery pipe 34 to recover the pressure building gas to be removed to the storage tank (31).

In addition, the recovery pipe 34 may recover the boil-off gas (BOG) generated by the vaporization of the liquefied fuel gas in the fuel tank 21 to the storage tank 31 during the refueling process.

The amount of boil-off gas generated in the fuel tank 21 receiving oil may be much higher than the boil-off gas generated in the storage tank 31. If the boil-off gas is continuously generated, the pressure of the fuel tank 21 is excessively increased. Therefore, external discharge of the boil-off gas is required. Since the boil-off gas is a flammable material, it is dangerous to process the boil-off gas on its own in the vessel 20.

Therefore, in the present embodiment, the recovery pipe 34 may reduce the risk of treating the boil-off gas in the vessel 20 by allowing the boil-off gas generated in the fuel tank 21 to be recovered to the storage tank 31.

The recovery pipe 34 may extend to the outside in communication with the upper portion of the storage tank 31.

The vessel 20 has a connector 22 for coupling the oil supply pipe 32 and the recovery pipe 34, and the fuel tank 21 communicates the liquefied fuel gas of the oil supply pipe 32 in communication with the oil supply pipe 32. An oil supply connecting pipe 23 to guide the gas, and a recovery connecting pipe 24 communicating with the recovery pipe 34 to guide the gas of the fuel tank 21 to the storage tank 31 are provided. When liquefied fuel gas is supplied to the vessel 20, the fuel supply pipe 32 and the recovery pipe 34 are coupled to the connector 22 to communicate with the fuel supply connection pipe 23 and the recovery connection pipe 24, respectively, so that the fuel tank ( 21) can enable oil supply.

As shown in FIG. 3, an embodiment of the present invention may include a coupling device 50 for coupling the oil supply pipe 32 and the recovery pipe 34 with the connector 22 of the vessel 20. . The coupling device 50 includes an arm 51 for receiving the oil supply pipe 32 and the recovery pipe 34, a control unit 53 for adjusting the arm 51, and a driving unit for driving the arm 51 ( The controller 55 may further include a controller 55 for controlling the driver 54 according to the signal of the driver 54 and the controller 53.

The arm 51 may be provided as a heat insulating material to assist heat insulation of the oil supply pipe 32 and the recovery pipe 34, and may include an at least one joint part 51a to facilitate movement. In addition, the end of the arm 51 is formed to be connected to the connector 22 of the vessel 20, when the arm 51 is connected to the connector 22, the oil supply pipe 32 and the recovery pipe 34 of the operator Selective communication with the fuel tank 21 is enabled or operated automatically.

The control unit 53 is for applying an input signal for the operator to move the arm 51, the signal applied from the control unit 53 is transmitted to the drive unit 54 through the control unit 55 to the arm 51 ) Coupled to the connector 22, or by separating the arm 51 coupled to the connector 22 to be moved to the offshore platform (10).

The control unit 53 and the control unit 55 may be provided on the offshore platform 10 so that an operator on the offshore platform 10 may drive the arm 51 using the control unit 53. It is also possible to be provided at the position 3 to drive the arm 51 remotely through the operator 53.

In addition, when an emergency occurs during refueling, the arm 51 may be quickly disconnected from the connector 22 to safely shut off the refueling even in an emergency.

In addition, the oil supply pipe 32 and the recovery pipe 34 is not accommodated in the arm 51 can be configured that each is directly connected to the connector 22, of course.

As shown in FIG. 2, the oil supply system 30 may further include a liquefaction device 60 for liquefying the gas in the storage tank 31.

The gas in the storage tank 31 may be a gas recovered from the fuel tank 21 or a gas generated by vaporizing the liquefied fuel gas inside the storage tank 31.

The liquefaction apparatus 60 may liquefy the gas recovered from the fuel tank 21, or liquefy the boil-off gas in the storage tank 31 to return to the storage tank 31.

In this way, by liquefying the gas in the storage tank 31 using the liquefaction apparatus 60, it is possible to reduce the energy waste.

As shown in FIGS. 2 and 4, the offshore platform 10 of the embodiment includes a fuel tank 21, a fuel supply connecting pipe 23 extending from the fuel tank 21, a recovery connecting pipe 24, and a storage tank ( 31 may further include a purging device 40 using nitrogen gas, which is an inert gas, to purge components of the oil supply system, such as the oil supply pipe 32 and the recovery pipe 34 extending from 31.

The purging device 40 includes a gas supply unit 41, a gas supply line 42, and a purging valve 43 that opens or closes the gas supply line and adjusts the opening degree.

The gas supply unit 41 is composed of a membrane module, an air compressor, an electric motor, a cooling device, a control panel, and the like, and a conventional gas generator for filtering and compressing air to extract nitrogen gas, and nitrogen gas storage filled with nitrogen gas. It may include a tank.

The gas supply line 42 is provided to be connected to the oil supply pipe 32 and the recovery pipe 34, the oil supply connection pipe 23, and the recovery connection pipe 24 in which the boil-off gas remains, as shown in FIG. By being connected to 22, the oil supply connection pipe 23, the recovery connection pipe 24, and the fuel tank 21 can be purged. In addition, the gas supply line 42 may be connected to the oil supply pipe 32 and the recovery pipe 34 to purge the oil supply pipe 32 and the recovery pipe 34.

In this case, the purging device 40 may be provided with the same coupling device (not shown) as the coupling device 50 for coupling the oil supply pipe 32 and the recovery pipe 34 with the connector 22, the gas supply line 42 may be easily coupled to the connector 22 by a coupling device (not shown).

In this way, by providing the purging device 40 on the offshore platform 10, it is possible to remove the configuration of the purging device 40 provided in the existing vessel 20 to maintain the construction cost and vessel equipment of the vessel 20 and Operation costs can be reduced.

Hereinafter will be described the operation of the offshore platform of one embodiment.

First, when the vessel 20 needing lubrication approaches the offshore platform 10 and the position is fixed, as shown in FIG. 4, the purging device 40 of the offshore platform 10 is connected to the connector 22 of the ship 20. ) To purge the fuel supply connecting pipe 23, the recovery connecting pipe 24 and the fuel tank 21 of the vessel 20.

Thereafter, as shown in FIG. 3, the arm 51 is moved toward the ship 20 using the control unit 53 of the offshore platform 10 to connect the oil supply pipe 32 and the recovery pipe 34 to the connector ( 22).

Next, the pump 33 is driven to refuel the liquefied fuel gas in the storage tank 31 to the fuel tank 21, and at least one of the pressure building gas and the evaporated gas of the fuel tank 21 is stored in the storage tank 31. ) And the liquefaction apparatus 60 reliquefies any one or more of the compressed building gas and the evaporated gas introduced into the storage tank 31, and then reintroduces the liquid into the storage tank 31.

After completing the oil supply to the fuel tank 21 through the above process, the oil supply pipe 32 and the recovery pipe 34 is separated from the connector 22 and moved to the offshore platform 10.

Thereafter, if necessary, purging the oil supply pipe 32 and the recovery pipe 34 by using the purging device 40, and purging the fuel supply connection pipe 23 and the recovery connection pipe 24 and the fuel tank 21. You can also do

The following describes a liquefied fuel gas refueling system according to another embodiment.

5 is a system diagram showing a liquefied fuel gas oil supply system according to another embodiment.

Another embodiment may include an evaporation gas treatment device 70 instead of a liquefaction device as shown in FIG. 5.

The boil-off gas treatment apparatus 70 may include a discharge device for blowing the gas in the storage tank 31 to the outside, or a gas combustion device for burning and discharging the gas to the outside.

The gas combustion device may be, for example, a gas compression unit (GCU) or a flare.

The boil-off gas treatment device 70 may be provided in the liquefaction device 60 and optionally the oil supply system 30, but may be provided together with the liquefaction device 60 although not shown.

Next, a liquefied fuel gas oil supply system according to another embodiment will be described.

6 is a system diagram showing a liquefied fuel gas oil supply system according to another embodiment.

In one embodiment, a pump 33 that directly pumps the liquefied fuel gas in the storage tank 31 to the ship 20 is used as a supply device. In another embodiment, the supply device is illustrated in FIG. 6. It may include a vaporizer 80. The remaining configuration may be the same as the configuration of the embodiment.

The vaporization device 80 forcibly vaporizes the liquefied fuel gas in the storage tank 31 and provides the pressure of the evaporated gas generated by the vaporization to the storage tank 31 to supply the liquefied fuel gas in the storage tank 31. Refuel to ship 20.

The vaporization device 80 is one end is located in the lower portion in the storage tank 31 and the other end is located in the upper portion in the storage tank 31, the intermediate portion extends to the outside of the storage tank 31 and the vaporization tube ( A vaporization pump 82 provided at one end of the 81, a vaporizer 83 provided at an intermediate portion of the vaporization pipe 81, and a valve provided at an outlet side of the vaporizer 83 to adjust the opening degree of the vaporization pipe 81 ( 84).

The vaporizer 83 may be, for example, a Shell & Tube type vaporizer using unheated seawater as a heat source.

The valve 84 is for controlling the pressure of the evaporated gas discharged from the vaporizer 83 and delivered to the storage tank 31, the pressure of the evaporated gas delivered to the storage tank 31 by adjusting the opening degree, that is, the evaporated gas You can adjust the amount.

The valve 84 may be provided with a pressure regulator (not shown). A pressure regulator (not shown) measures the pressure in the storage tank 31 and adjusts the opening degree of the valve 84 according to the measured value.

When the vaporization apparatus 80 provided as described above is driven, the liquefied fuel gas in the storage tank 31 is sent to the vaporizer 83 along the vaporization pipe 81 by the vaporization pump 82 and is forcibly vaporized in the vaporizer 83. .

The pressure of the boil-off gas forcibly vaporized in the vaporizer 83 is returned to the storage tank 31 along the vaporization pipe 81. The pressure of the boil-off gas acts as a supply pressure for refueling the liquefied fuel gas in the storage tank 31 to the vessel 20.

When the liquefied fuel gas is vaporized, its volume is greatly increased compared to the liquefied state, so that the high pressure required to refuel the liquefied fuel gas to supply the liquefied fuel gas of the storage tank 31 to the fuel tank 21 can be realized. As such, when the vaporization device 80 is used, the liquefied fuel gas may be supplied to the fuel tank 21 even when the vaporization pump 82 having a smaller capacity than the pump 33 of the embodiment is used.

As described above, the present embodiment installs the marine platform for marine refueling at predetermined intervals, so that the liquefied fuel gas can be used at sea in ships and other floating structures that use liquefied fuel gas as fuel without using onshore refueling facilities. Supply is possible.

In order to store liquefied fuel gas in a storage tank of an offshore platform, at least one of a method using a liquefied fuel gas carrier such as a LNG carrier and a pipeline connected to a land or offshore liquefied fuel gas storage facility are used. One way may be considered.

In addition, it is easy to construct the refueling infrastructure because there are fewer restrictions on the location selection, etc. than by installing the offshore platform for refueling on the sea, and the ship provides the refueling by installing the offshore refueling platform in the sea near the main routes. Hazardous energy losses from moving to onshore oil supply can also be reduced.

10: offshore platform, 20: ship,
21: fuel tank, 22: connector,
30: oil supply system, 31: storage tank,
32: oil supply pipe, 33: pump,
34: recovery pipe, 40: purging device,
50: coupling device, 51: arm
53: control unit, 54: drive unit,
55: control unit, 60: liquefaction apparatus,
70: boil-off gas treatment device, 80: vaporization device.

Claims (6)

Liquefied fuel gas storage tank,
An oil supply pipe for supplying liquefied fuel gas of the storage tank to a ship;
A recovery pipe for recovering gas in the fuel tank of the ship to the storage tank;
A supply device for supplying the liquefied fuel gas of the storage tank to the fuel tank;
A marine platform for liquefied fuel gas refueling comprising a purging device for removing impurities of at least one of the fuel supply pipe, the recovery pipe and the fuel tank of the gas propulsion vessel. The method of claim 1,
The vessel includes a connector for connecting the oil supply pipe and the recovery pipe,
The offshore platform for liquefied fuel gas refueling for receiving the oil supply pipe and the recovery pipe further comprises an arm formed to be coupled to the fuel tank. The method of claim 2,
A control unit for adjusting the arm,
A control unit which receives a signal of the control unit;
The offshore platform for liquefied fuel gas refueling comprising a drive for steering the arm in accordance with the signal of the controller. 4. The method according to any one of claims 1 to 3,
And a liquefaction apparatus for liquefying the gas recovered to the storage tank or re-liquefying the evaporated gas generated from the storage tank to return to the storage tank. 4. The method according to any one of claims 1 to 3,
The supply apparatus is a marine platform for liquefied fuel gas refueling containing a pump which is accommodated in the storage tank to pump the liquefied fuel gas. 4. The method according to any one of claims 1 to 3,
The supply device includes a vaporization device for vaporizing the liquefied fuel gas of the storage tank,
The liquefied fuel gas of the storage tank is liquefied fuel gas offshore platform for refueling the fuel tank by the pressure of the gas vaporized by the vaporizer.

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