KR101670873B1 - Apparatus for feeding combustibles on a marine structure - Google Patents

Abstract

The present invention relates to a flammable material transfer device capable of safely transferring a flammable material without risk of explosion or fire by using a hydraulic motor as a drive source for operating a compressor or a pump when transferring a flammable material such as LNG on an offshore structure, ≪ / RTI >
According to the present invention, there is provided an apparatus for transferring a combustible material to an offshore structure used for transferring a combustible material from one place to another in an offshore structure, comprising: Means; A hydraulic motor for driving said pressing means; Wherein the hydraulic motor is installed in the danger zone together with the pressurizing means, and a conveying method using the same.

Description

[0001] APPARATUS FOR FEEDING COMBUSTIBLES ON A MARINE STRUCTURE [0002]

The present invention relates to an apparatus and a method for safely transferring a combustible material on an offshore structure, and more particularly, to a method and apparatus for transferring a combustible material such as LNG on an offshore structure using a hydraulic motor as a drive source for operating a compressor or a pump To a combustible material transferring apparatus and method capable of safely transferring a combustible material without risk of explosion or fire.

In recent years, consumption of liquefied gas such as LNG (Liquefied Natural Gas) and LPG (Liquefied Petroleum Gas) has been rapidly increasing worldwide. The liquefied gas is transported in a gaseous state via land or sea gas piping, or is transported to a distant consumer site stored in a liquefied gas carrier in a liquefied state. Liquefied gas such as LNG or LPG is obtained by cooling natural gas or petroleum gas at a very low temperature (approximately -163 ° C. in the case of LNG), and its volume is significantly reduced compared to when it is in a gaseous state, .

The liquefied gas carrier, such as an LNG carrier, is used to load the liquefied gas with the liquefied gas and then to the sea to unload the liquefied gas to the onshore site. For this purpose, a storage tank capable of withstanding the extremely low temperature of the liquefied gas ).

Examples of the offshore structure provided with the storage tank capable of storing the liquefied gas at such a low temperature state include ships such as LNG RV (Regasification Vessel), LNG FSRU (Floating, Storage and Regasification Unit), LNG FRU Regulation Unit, LNG FPSO (Floating, Production, Storage and Off-loading) and BMPP (Barge Mounted Power Plant).

LNG RV is a LNG regeneration facility installed on a liquefied natural gas carrier capable of self-propulsion and floating. LNG FSRU is a structure that stores liquefied natural gas unloaded from an LNG carrier offshore from offshore and then supplies the natural gas to the customer when necessary. LNG FRU is similar to LNG FSRU It is a structure that receives LNG from the outside because it does not have a large storage tank. LNG FPSO is a structure used to transport mined LNG stored in this storage tank to LNG transport, if necessary, after liquefied natural gas is purified directly from the sea. And BMPP is a structure that is used to produce electricity at sea by installing a power plant on a barge.

In this specification, an offshore structure is a concept including all types of liquefied gas carrier such as LNG carrier, LNG RV, LNG FPSO, Oil FPSO, LNG FSRU, LNG FRU and BMPP.

However, since the LNG is a flammable gas, in the above-described offshore structure in which LNG is carried or used, a zone in which flammable gas is likely to be introduced is designated as a dangerous zone. In this zone, Explosion-proof equipment is used to prevent fire.

Especially recently, when heavy oil or MDO (Marine Diesel Oil), which is conventionally used as fuel for various engines in a ship, is burned, the seriousness of environmental pollution caused by various harmful substances contained in exhaust gas arises, Regulations for various engines of ships using oil as fuel have been strengthened, and the cost for meeting such regulations is increasing.

Accordingly, an engine that can use clean fuel such as LNG, LPG, CNG, or DME, which is gaseous fuel, has been developed instead of using oil such as heavy oil or MDO as a fuel oil or using only a minimum amount of oil, And the like.

However, LNG, which is a clean fuel, is a combustible material. When these materials are used as fuel in propulsion or power generation engines, it is necessary to supply fuel to the engine at all times during operation of the offshore structure. It is necessary to ensure the safety of the apparatus.

As a result, research and development of a device and method for transferring flammable materials to offshore structures need to be continuously carried out in order to safely use a transfer device for transferring flammable materials such as LNG from one place to another.

SUMMARY OF THE INVENTION The present invention has been made to solve the conventional problems as described above and it is an object of the present invention to provide a flammable material transfer device capable of safely transferring flammable materials by using a hydraulic motor, And to provide a material transfer apparatus and method.

Further, the present invention is characterized in that, by using a hydraulic motor, the pressing means of the transfer device for pressurizing the combustible material for transfer and the drive means, i.e., the hydraulic motor, for operating the pressurizing means can be installed together in the same space, The present invention provides an apparatus and method for transferring a combustible material to an offshore structure, which is advantageous from the viewpoint of maintenance and space utilization, as compared with a case where the drive means is installed in a separate space.

According to an aspect of the present invention, there is provided an apparatus for transferring a combustible material to an offshore structure, which is used for transferring a combustible material from one place to another in an offshore structure, A pressing means for moving the pressing means; A hydraulic motor for driving the pressing means; Lubricating oil supply means for supplying lubricating oil to the hydraulic motor; And the hydraulic motor is installed in the same space as the pressurizing means, and a combustible material transfer device for an offshore structure can be provided.

The lubricating oil supply means may be a lubricating oil pump for supplying lubricating oil to the hydraulic motor. The hydraulic motor and the lubricating oil pump may be installed together in the same space as the pressing means.

The combustible material transfer device for an offshore structure according to the present invention may further include a hydraulic motor for a lubricant pump for driving the lubricant pump. The lubricating oil pump and the hydraulic motor for the lubricating oil pump may be installed together in the same space as the hydraulic motor.

The lubricating oil may be supplied to the interior of the hydraulic motor through a lubricating oil supply line extending from the lubricating oil pump to the hydraulic motor and returned to the lubricating oil pump through a lubricating oil return line extending from the hydraulic motor to the lubricating oil pump .

The supply of the working fluid to the hydraulic motor and the hydraulic motor for the lubricant pump may be performed by a dedicated hydraulic pressure generator. The dedicated hydraulic pressure generator includes a first hydraulic pump for supplying a working fluid to the hydraulic motor, a second hydraulic pump for supplying a working fluid to the hydraulic motor for the lubricant pump, and a reservoir capable of storing the working fluid .

Wherein the working fluid stored in the reservoir is supplied to the hydraulic motor via a first supply line after being pressurized by the first hydraulic pump and returns to the reservoir through a first return line, And then supplied to the hydraulic motor for the lubricant pump through the second supply line and returned to the reservoir through the second return line.

According to the present invention, the working fluid used for driving the hydraulic motor can be utilized as the lubricating oil supplied for lubrication of the hydraulic motor.

The supply of the working fluid to the hydraulic motor and the supply of the lubricating oil to the hydraulic motor may be performed by a dedicated hydraulic pressure generator. The dedicated hydraulic pressure generator may include a first hydraulic pump for supplying a working fluid to the hydraulic motor, a second hydraulic pump for supplying lubricating oil to the hydraulic motor, and a reservoir capable of storing a working fluid . At this time, the lubricating oil supply means may be the second hydraulic pump.

The working fluid stored in the reservoir is supplied to the hydraulic motor through the first supply line after being pressurized by the first hydraulic pump to operate the hydraulic motor and return to the reservoir through the first return line Is supplied as lubricant to the hydraulic motor through the second supply line after being pressurized by the second hydraulic pump, and can return to the reservoir via the second return line.

The supply of the working fluid to the hydraulic motor may be performed by a dedicated hydraulic pressure generator for the hydraulic motor.

A hydraulic line for supplying a working fluid to the hydraulic motor may be installed between the dedicated hydraulic pressure generator and the hydraulic motor.

The dedicated hydraulic pressure generator may include two hydraulic pumps in preparation for failure.

The pressurizing means may be a pump or a compressor.

The pressurizing means allows the combustible material to be compressed into 200 to 400 bara and then supplied as fuel to the MEGI engine.

According to another aspect of the present invention, there is provided a combustible material transfer method for an offshore structure used for transferring a combustible material from a place to another place in an offshore structure, the method comprising: operating a hydraulic motor by hydraulic pressure supplied from a hydraulic pressure generator; Wherein the pressurizing means for pressurizing the combustible material through the drive shaft extending from the hydraulic motor is operated to transfer the combustible material in one direction, the hydraulic motor being supplied with lubricating oil by the lubricating oil supply means, There is provided a method of conveying a combustible material of an offshore structure, which is installed together in a space.

According to the present invention, there can be provided an apparatus and a method for transferring a combustible material of an offshore structure using a hydraulic motor which is free from the occurrence of electric sparks as a driving source included in a transfer device for a combustible material.

Accordingly, the combustible material transferring apparatus and method of the present invention can safely transfer the combustible material

According to the apparatus and method for transferring a combustible material of the present invention, by using the hydraulic motor, the pressure means of the transfer device for pressurizing the combustible material for transfer and the drive means for operating the pressure means, that is, the hydraulic motor, It is easy to align the axes and to seal the space, compared with the case where the pressurizing means and the driving means are provided in separate spaces, and it is advantageous in terms of maintenance and space utilization.

In addition, the apparatus and method for transferring combustible materials of the present invention are characterized in that a hydraulic motor used in place of an electric motor is relatively small in size compared to an electric motor. Therefore, compared with a large-sized offshore structure, It can be easily applied to a structure.

1 is a view for explaining a combustible material conveying device driven by an electric motor,
2 is a view for explaining a combustible material conveying apparatus driven by a hydraulic motor according to a first embodiment of the present invention,
3 is a view for explaining a combustible material conveying device driven by a hydraulic motor according to a second embodiment of the present invention,
Fig. 4 is a view for explaining a combustible material conveying device driven by a hydraulic motor according to a third embodiment of the present invention, and Fig.
Fig. 5 is a view for explaining a combustible material conveying device driven by a hydraulic motor according to a fourth embodiment of the present invention. Fig.

In general, among the waste gases emitted from vessels, those regulated by the International Maritime Organization are nitrogen oxides (NOx) and sulfur oxides (SOx), and in recent years they have also been trying to regulate the emission of carbon dioxide (CO ₂ ) have. Particularly, in the case of nitrogen oxide (NOx) and sulfur oxides (SOx), it was raised through the Protocol of the Maritime Pollution Prevention Convention (MARPOL) in 1997, In May, the requirements for the fermentation were satisfied and the regulations are being implemented.

Accordingly, various methods for reducing nitrogen oxide (NOx) emissions have been introduced in order to meet these requirements. Of these methods, high-pressure natural gas injection engines for offshore structures such as ships such as LNG carriers, for example, MEGI engines Has been developed and used. The ME-GI engine is seen as an environmentally friendly next-generation engine that can reduce pollutant emissions by 23%, nitrogen compounds 80%, and sulfur compounds 95% or more, compared with diesel engines of the same class.

Such a MEGI engine can be installed in an offshore structure such as an LNG carrier or an LNG carrier that stores and transports LNG in a cryogenic storage tank. In this case, natural gas is used as fuel for the engine. A high-pressure fuel gas supply pressure of about 200 to 400 bara (absolute pressure) is required for the engine depending on the load.

The MEGI engine can also be used directly for propelling, for which the MEGI engine consists of a two-stroke engine rotating at low speed. That is, the MEGI engine is a low-speed two-stroke high-pressure natural gas injection engine.

The transport apparatus described herein can be used in a fuel gas supply system (FGS system) for supplying fuel to a MEGI engine.

In the present specification, the term "offshore structure" is used to include all kinds of liquefied gas carriers such as LNG carriers, LNG RVs, container ships, and the like, as well as LNG FPSO, Oil FPSO, LNG FSRU, LNG FRU and BMPP.

The term 'combustible material' as used herein refers not only to fuel used for various engines mounted on an offshore structure for propulsion, power generation, etc., but also to a storage tank for transportation as a cargo in the aforementioned offshore structure It is a concept that includes everything.

In the present specification, the term " space " means a zone formed by partition walls, and the expression " in the same space "means that two or more equipments are installed together in one zone defined by a partition wall Can be regarded as doing.

Fig. 1 shows an example of a transfer device installed on an offshore structure and used for transferring a combustible material such as LNG and the like. The conveying apparatus shown in Fig. 1 uses an electric motor as a driving source.

Referring to FIG. 1, a transfer device for transferring a combustible material such as LNG or natural gas is provided in a transfer pipe 2 in a pressurized space (zone 0) to pressurize a combustible material, (3) adjacent to the pressurized space (1) which is to be treated as a dangerous area due to the risk of explosion and which is partitioned by the partition wall (4) And an electric motor 12 provided as a driving means for driving the pressing means 10.

In the present specification, the 'pressurized space' means a space in which the pressurizing means 10 for pressurizing the combustible material for conveying the combustible material is installed, and the 'adjacent space' means a space between the 'pressurized space' It means adjacent space. The pressurized space shall be treated as a hazardous area where flammable material may leak from the pressurized means and explosion may occur.

As the pressurizing means 10, a pump may be used for transferring a combustible substance in a liquid state such as LNG, and a compressor may be used for transferring a gaseous combustible substance such as a natural gas (BOG).

The pressurizing space (1) as a pump room or a compressor room is an area which is likely to explode due to leakage of a combustible material. Therefore, in order to ensure safety, an equipment Can not be installed.

On the other hand, the electric motor 12 as the driving means of the pressurizing means may be an explosion-proof electric motor. However, even in the case of the explosion-proof electric motor, the electric motor 12 is not installed in a space May be required.

The electric motor 12 operated by electricity can be installed in the adjacent space 3 as a motor room divided by the partition wall 4 from the pressurizing space 1, The driving force of the pressing member 12 is transmitted to the pressing means 10 through the driving shaft 13 passing through the partition wall 4. Electricity supply to the electric motor 12 can be performed by the power generation device 15 installed in the outer (safety zone) of the motor room.

The portion of the drive shaft 13 penetrating the partition wall 4 must be sealed by the sealing bearing means 5 so that the inflow of the combustible material can be blocked.

Since the electric motor can be installed in a separate space defined by the partition wall from the pressurizing means of the combustible material, the combustible material transfer device and method capable of safely transferring the combustible material can be provided. Can be provided.

Since the conveying apparatus shown in Fig. 1 is constructed by connecting the pressing means 10 and the electric motor 12, which are provided in separate spaces with the partition 4 interposed therebetween, by the drive shaft 13, The inventors have found that there is a problem that much time and effort are required for aligning the drive shaft 13 when the motor 10 and the electric motor 12 are installed in the respective spaces.

In addition, since the exhaust device 17 must be provided in the adjacent space 3 in contact with the pressurizing space 1 where the combustible material may leak, in consideration of the inflow of the combustible material possibly present, It is difficult to reduce the size of the adjacent space 3, and the space utilization is also reduced.

Hereinafter, the configuration and operation of the embodiment according to the present invention will be described in detail with reference to FIG. 2 and FIG. In addition, the following examples can be modified in various forms, and the scope of the present invention is not limited to the following examples.

Fig. 2 is a view for explaining a combustible material conveying device driven by a hydraulic motor according to a first embodiment of the present invention.

2, a transfer device for transferring a combustible material such as LNG or natural gas is installed in a transfer pipe 2 in a pressurized space (zone 0) to pressurize a combustible material, A hydraulic motor 10 as a driving means for driving the pressing means 10 is provided in the pressurizing space 1 together with the pressing means 10 20).

As the pressurizing means 10, a pump may be used for transferring a combustible substance in a liquid state such as LNG, and a compressor may be used for transferring a gaseous combustible substance such as a natural gas (BOG).

The pressure space (1) as a pump room or a compressor room is an area that may explode due to leakage of combustible materials. Therefore, equipment that uses electricity that can cause sparks in the pressure space Can not be installed. Since the hydraulic motor 20 is not an apparatus using electricity, it can be installed in the pressurizing space 1. [

By using the hydraulic motor in place of the electric motor 12 as the drive means for operating the pressurizing means 10 such as a pump or a compressor provided in the pressurizing space 1 as described above, It is possible to provide an apparatus and method for transferring a combustible material advantageous in terms of maintenance and space utilization without installing an electric motor in the pressurizing space 1. [

A driving shaft 21 is connected between the hydraulic motor 20 and the pressing means 10 and the driving force of the hydraulic motor 20 can be transmitted to the pressing means 10 through the driving shaft 21.

The supply of the working fluid to the hydraulic motor 20 can be simply performed by a hydraulic pressure generator already installed in the offshore structure. However, according to the present embodiment, the dedicated hydraulic pressure generator 23 for only the hydraulic motor 20 for driving the pressurizing means 10 of the combustible material is provided, and the dedicated hydraulic pressure generator 23 and the hydraulic motor 20 So that the hydraulic motor 20 is supplied with the working fluid.

The dedicated hydraulic pressure generator 23 may include two hydraulic pumps 24 having the same specifications in preparation for failure.

The hydraulic motor 20 of this embodiment may be a variable speed hydraulic motor whose speed can be varied. When a variable speed type hydraulic motor is used, it is not necessary to use a separate speed reducing device, so it requires less installation space and is more advantageous for maintenance than an electric motor requiring a reduction gear such as a reduction gear.

Fig. 3 is a view for explaining a combustible material conveying device driven by a hydraulic motor according to a second embodiment of the present invention.

The combustible material transferring apparatus according to the second embodiment of the present invention shown in Fig. 3, like the combustible material transferring apparatus according to the first embodiment of the present invention described above with reference to Fig. 2, A pressing means 10 installed in the conveying pipe 2 in the conveying pipe 1 for conveying the combustible material in one direction in the conveying pipe 2 by pressurizing the combustible material; And a hydraulic motor 20 provided as a driving means for driving the pressing means 10.

As the pressurizing means 10, a pump may be used for transferring a combustible substance in a liquid state such as LNG, and a compressor may be used for transferring a gaseous combustible substance such as a natural gas (BOG).

By using a hydraulic motor in place of the electric motor 12 as the driving means for operating the pressing means 10 such as a pump or a compressor provided in the pressurizing space 1 as a pump room or a compressor room , It is possible to provide an apparatus and method for transferring a combustible material which is advantageous in terms of maintenance and space utilization without installing an electric motor in the pressurizing space 1. [

Hereinafter, the difference from the first embodiment will be mainly described in the combustible material conveying apparatus according to the second embodiment. The same reference numerals are assigned to the same components, and a detailed description thereof will be omitted.

The combustible material transfer device according to the second embodiment may further include a partition 6 partitioning the pressurizing space 1 into two or more. Of the two spaces partitioned by the partition wall 6, the one provided with the pressure means 10 should still be treated as a dangerous area which may still explode. The space on the opposite side of the space in which the pressing means 10 is provided around the partition wall 6 can be handled as an adjacent space 7 adjacent to the pressurizing space 1 which is a dangerous area.

Various equipment (8) which can not be installed in the pressurized space (1) can be installed in the adjacent space (7) due to risk of fire or explosion. Examples of the equipment 8 installed in the adjacent space 7 include various devices involved in supplying fuel gas to the engine and a unit for controlling the devices.

The combustible material transfer device of the present invention can be installed on the deck 31 and the hydraulic pressure generator 23 provided for supplying the working fluid to the hydraulic motor 20 is provided below the deck 31 And may be disposed in an engine room (or machine room) 32.

3, the conveying pipe 2 is shown extending from the lower side of the deck 31 through the pressurizing space 1, but this is merely an example, and the conveying pipe 2 shown in Figs. 2 and 3, The present invention is not limited to the extending direction of the guide grooves.

Fig. 4 is a view for explaining a combustible material conveying device driven by a hydraulic motor according to a third embodiment of the present invention.

The combustible material transfer device according to the third embodiment of the present invention shown in Fig. 4 is similar to the combustible material transfer device according to the first embodiment of the present invention described above with reference to Fig. 2, A pressing means 10 installed in the conveying pipe 2 in the conveying pipe 1 for conveying the combustible material in one direction in the conveying pipe 2 by pressurizing the combustible material; And a hydraulic motor 20 provided as a driving means for driving the pressing means 10.

As the pressurizing means 10, a pump may be used for transferring a combustible substance in a liquid state such as LNG, and a compressor may be used for transferring a gaseous combustible substance such as a natural gas (BOG).

The pressure space (1) as a pump room or a compressor room is an area that may explode due to leakage of combustible materials. Therefore, equipment that uses electricity that can cause sparks in the pressure space Can not be installed. Since the hydraulic motor 20 is not an apparatus using electricity, it can be installed in the pressurizing space 1. [

By using the hydraulic motor in place of the electric motor 12 as the drive means for operating the pressurizing means 10 such as a pump or a compressor provided in the pressurizing space 1 as described above, It is possible to provide an apparatus and method for transferring a combustible material advantageous in terms of maintenance and space utilization without installing an electric motor in the pressurizing space 1. [

A driving shaft 21 is connected between the hydraulic motor 20 and the pressing means 10 and the driving force of the hydraulic motor 20 can be transmitted to the pressing means 10 through the driving shaft 21.

The combustible material transferring apparatus according to the third embodiment of the present invention shown in Fig. 4 comprises a lubricating oil pump 40 for supplying lubricating oil to the hydraulic motor 20 provided in the pressurizing space 1, And the hydraulic motor 50 for the lubricating oil pump for driving the hydraulic motor 20 are installed in the pressurizing space 1 together with the hydraulic motor 20, Do.

In order to smoothly drive the hydraulic motor 20, lubrication between the parts to be moved is required. Further, when the combustible material is LNG, the temperature of the LNG is extremely low at about -163 DEG C at room temperature, so that the temperature of the pressurizing means 10 becomes very low. Accordingly, the hydraulic motor 20 installed near the pressurizing means 10 and connected to the drive shaft 21 may also be affected by the low temperature. If the ambient temperature is low, the viscosity of the lubricating oil is increased, and there is a possibility that the lubricating operation may not be performed well, so that circulation of the lubricating oil may be required.

The hydraulic motor 20 of the present embodiment is connected to the pressurizing means 10 for pressurizing the combustible material through the drive shaft 21 so that the lubricant is supplied to the hydraulic motor 20 It is good to have a circulating structure. To this end, the lubricating oil pump 40 and the hydraulic motor 50 for the lubricating oil pump are provided at positions spaced apart from the pressing means 10 and the hydraulic motor 20, respectively, in the pressing space 1.

The driving shaft 21 is connected between the hydraulic motor 20 and the pressing means 10 so that the driving force of the hydraulic motor 20 can be transmitted to the pressing means 10, The drive shaft 51 is connected between the hydraulic motor 50 for lubricating oil pump and the lubricating oil pump 40 so that the driving force can be transmitted to the lubricating oil pump 40. [

The lubricating oil is supplied to the inside of the hydraulic motor 20 through the lubricating oil supply line 41 extending from the lubricating oil pump 40 to the hydraulic motor 20 in order to lubricate between the parts included in the hydraulic motor 20. [ And return to the lubricating oil pump 40 through the lubricating oil return line 42 extending from the hydraulic motor 20 to the lubricating oil pump 40.

On the other hand, the supply of the working fluid to the hydraulic motor 20 and the hydraulic motor 50 for the lubricating oil pump can be simply performed by a hydraulic pressure generator already installed in the offshore structure. However, according to the present embodiment, the hydraulic motor 20 for driving the pressurizing means 10 of the combustible material and the dedicated hydraulic pressure generator 53 for the hydraulic motor 50 for the lubricant pump driving the lubricant pump 40 So that the hydraulic motor 20 and the hydraulic motor 50 for the lubricating oil pump are supplied with the working fluid.

The dedicated hydraulic pressure generator 53 includes a first hydraulic pump 24 for supplying a working fluid to the hydraulic motor 20 and a second hydraulic pump 24 for supplying a working fluid to the hydraulic motor 50 for the lubricant pump 54, and a reservoir 52 capable of storing working fluid.

As the first hydraulic pump 24, two hydraulic pumps having the same specifications may be included in the hydraulic pressure generator 53 in preparation for failure.

The working fluid stored in the reservoir 52 is supplied to the hydraulic motor 20 through the first supply line 25 after being pressurized by the first hydraulic pump 24 to operate the hydraulic motor 20, And can be returned to the reservoir 52 again via the first return line 26. Some or all of the working fluid returning through the first return line 26 as required can be supplied directly to the upstream side of the first hydraulic motor 24 of the first supply line 25 without passing through the reservoir 52 .

The working fluid stored in the reservoir 52 is supplied to the hydraulic motor 50 for the lubricant pump through the second supply line 55 after being pressurized by the second hydraulic pump 54, The motor 50 may be operated and returned to the reservoir 52 again via the second return line 56. [ Some or all of the working fluid returning through the second return line 56 as needed may be supplied directly to the upstream side of the second hydraulic motor 54 of the second supply line 55 without passing through the reservoir 52 .

According to the present embodiment, a first drain line 27 may be provided for use in discharging all of the working fluid in the hydraulic motor 20 for maintenance of the hydraulic motor 20. The first drain line 27 may extend from the lower end of the hydraulic motor 20, particularly the hydraulic motor 20, to the outside of the reservoir 52 or the hydraulic generator 53. The first drain line 27 is provided with a valve 28 and opens the valve 28 only when a drain operation is performed to drain the working fluid in the hydraulic motor 20 to the reservoir 52 for example.

According to the present embodiment, a second drain line 57 for use in discharging all the working fluid in the hydraulic motor 20 for the lubricating oil pump can be installed for maintenance of the hydraulic motor 50 for the lubricating oil pump have. The second drain line 57 may extend from the lower end of the hydraulic motor 50 for a lubricating oil pump, particularly the hydraulic motor 50 for a lubricating oil pump, to the outside of the reservoir 52 or the oil pressure generator 53. A valve 58 is provided in the second drain line 57 and the valve 58 is opened only when the drain operation is performed to drain the working fluid in the hydraulic motor 50 for the lubricant pump to the reservoir 52 .

The hydraulic motor 20 and the hydraulic motor 50 for the lubricating oil pump of the present embodiment may be a variable-speed hydraulic motor whose speed can be varied. When a variable speed type hydraulic motor is used, it is not necessary to use a separate speed reducing device, so it requires less installation space and is more advantageous for maintenance than an electric motor requiring a reduction gear such as a reduction gear.

Fig. 5 is a view for explaining a combustible material conveying device driven by a hydraulic motor according to a fourth embodiment of the present invention.

The combustible material transfer device according to the fourth embodiment of the present invention shown in Fig. 5 is similar to the combustible material transfer device according to the third embodiment of the present invention described above with reference to Fig. 4, A pressing means 10 installed in the conveying pipe 2 in the conveying pipe 1 for conveying the combustible material in one direction in the conveying pipe 2 by pressurizing the combustible material; And a hydraulic motor 20 provided as a driving means for driving the pressing means 10.

As the pressurizing means 10, a pump may be used for transferring a combustible substance in a liquid state such as LNG, and a compressor may be used for transferring a gaseous combustible substance such as a natural gas (BOG).

The pressure space (1) as a pump room or a compressor room is an area that may explode due to leakage of combustible materials. Therefore, equipment that uses electricity that can cause sparks in the pressure space Can not be installed. Since the hydraulic motor 20 is not an apparatus using electricity, it can be installed in the pressurizing space 1. [

By using the hydraulic motor in place of the electric motor 12 as the drive means for operating the pressurizing means 10 such as a pump or a compressor provided in the pressurizing space 1 as described above, It is possible to provide an apparatus and method for transferring a combustible material advantageous in terms of maintenance and space utilization without installing an electric motor in the pressurizing space 1. [

A driving shaft 21 is connected between the hydraulic motor 20 and the pressing means 10 and the driving force of the hydraulic motor 20 can be transmitted to the pressing means 10 through the driving shaft 21.

5 differs from the fourth embodiment in that the working fluid used for driving the hydraulic motor 20 is supplied to the hydraulic motor 20, As a lubricating oil to be supplied to the engine. Accordingly, the lubricating oil pump 40 and the hydraulic motor 50 for the lubricating oil pump included in the above-described fourth embodiment are not necessary in the fifth embodiment.

On the other hand, the supply of the working fluid to the hydraulic motor 20 can be simply performed by the hydraulic pressure generator already installed in the offshore structure. However, according to the present embodiment, the hydraulic motor 20 for driving the pressurizing means 10 of the combustible material and the dedicated hydraulic pressure generating device 53 for supplying the lubricating oil to the hydraulic motor 20 are provided, The motor 20 can be configured to receive the working fluid and the lubricating oil.

The dedicated hydraulic pressure generator 53 includes a first hydraulic pump 24 for supplying a working fluid to the hydraulic motor 20 and a second hydraulic pump 54 for supplying a working fluid as a lubricating oil to the hydraulic motor 20. [ And a reservoir 52 capable of storing the working fluid.

As the first hydraulic pump 24, two hydraulic pumps having the same specifications may be included in the hydraulic pressure generator 53 in preparation for failure.

The working fluid stored in the reservoir 52 is supplied to the hydraulic motor 20 through the first supply line 25 after being pressurized by the first hydraulic pump 24 to operate the hydraulic motor 20, And can be returned to the reservoir 52 again via the first return line 26. Some or all of the working fluid returning through the first return line 26 as required can be supplied directly to the upstream side of the first hydraulic motor 24 of the first supply line 25 without passing through the reservoir 52 .

The working fluid stored in the reservoir 52 is supplied as lubricating oil to the hydraulic motor 20 through the second supply line 55 after being pressurized by the second hydraulic pump 54, May be returned to the reservoir 52 again via the reservoir 56. Some or all of the working fluid returning through the second return line 56 as needed may be supplied directly to the upstream side of the second hydraulic motor 54 of the second supply line 55 without passing through the reservoir 52 .

According to the present embodiment, a first drain line 27 may be provided for use in discharging all of the working fluid in the hydraulic motor 20 for maintenance of the hydraulic motor 20. The first drain line 27 may extend from the lower end of the hydraulic motor 20, particularly the hydraulic motor 20, to the outside of the reservoir 52 or the hydraulic generator 53. The first drain line 27 is provided with a valve 28 and opens the valve 28 only when a drain operation is performed to drain the working fluid in the hydraulic motor 20 to the reservoir 52 for example.

Also, according to the present embodiment, a lubricant drain line 67 may be provided for use in discharging all the lubricating oil used in the hydraulic motor for maintenance of the hydraulic motor 20. The lubricant drain line 67 may extend from the lubricant circulating portion inside the hydraulic motor 20, particularly the hydraulic motor 20, to the outside of the reservoir 52 or the hydraulic generator 53. A valve 68 is provided in the lubricant drain line 67 and only opens the valve 68 when the drain operation is performed to drain the working fluid as lubricant in the hydraulic motor 20 to the reservoir 52 for example.

The hydraulic motor 20 of this embodiment may be a variable speed hydraulic motor whose speed can be varied. When a variable speed type hydraulic motor is used, it is not necessary to use a separate speed reducing device, so it requires less installation space and is more advantageous for maintenance than an electric motor requiring a reduction gear such as a reduction gear.

When the combustible material transfer device is constructed as described above, a combustible material can be safely transferred without fear of explosion or fire by using a hydraulic motor which is free from the occurrence of electric sparks as a driving source included in the transfer device for combustible materials

According to the apparatus and method for transporting a combustible material of the present invention, by using a hydraulic motor, the pressure means of the transfer device for pressing the combustible material for transfer and the drive means for operating the pressure means, that is, the hydraulic motor, It is not necessary to perform axial alignment or sealing of the space in comparison with the case where the pressurizing means and the driving means are provided in separate spaces, which is advantageous in terms of maintenance and space utilization.

Further, in the apparatus and method for transferring the combustible material of the present invention, since the hydraulic motor used in place of the electric motor has a relatively small size as compared with the electric motor, unlike the electric motor, there is no need to mount the speed reducer in the hydraulic motor. Compared with large-scale offshore structures, it can be easily applied to small and medium-sized offshore structures with narrow installation space.

Furthermore, when the present invention is applied to a ship carrying a cargo such as an LNG cargo ship or a container ship, the size of the space to be secured for the combustible material transfer apparatus is reduced, which is advantageous because the cargo transfer amount can be increased accordingly.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention will be.

1: Hazardous area
2: Feed pipe
3: adjacent area
4:
5: Sealing bearing means
10: Pressurizing means
12: Electric motor
13:
15: Generator
17: Exhaust system
20: Hydraulic motor
21:
23: Dedicated Hydraulic Generator
24: Hydraulic pump
25: Hydraulic line

Claims (15)

Claims 1. A combustible material transfer device for an offshore structure used to transfer combustible material from one location to another in an offshore structure,
Pressurizing means for conveying the combustible material in one direction by pressurizing the combustible material;
A hydraulic motor for driving the pressing means;
Lubricating oil supply means for supplying lubricating oil to the hydraulic motor;
/ RTI >
The hydraulic motor is installed together in the same space as the pressing means,
The lubricating oil supply means is a lubricating oil pump for supplying lubricating oil to the hydraulic motor,
The hydraulic motor and the lubricating oil pump are installed together in the same space as the pressing means,
The lubricating oil is supplied to the interior of the hydraulic motor through a lubricating oil supply line extending from the lubricating oil pump to the hydraulic motor and is capable of returning to the lubricating oil pump through a lubricating oil return line extending from the hydraulic motor to the lubricating oil pump , A device for transferring flammable materials to offshore structures. delete The method according to claim 1,
Further comprising a hydraulic motor for a lubricant pump for driving the lubricant pump,
Wherein the lubricating oil pump and the hydraulic motor for the lubricating oil pump are installed together in the same space as the hydraulic motor. delete The method of claim 3,
Wherein supply of the working fluid to the hydraulic motor and the hydraulic motor for the lubricant pump is performed by a dedicated hydraulic pressure generator,
The dedicated hydraulic pressure generator includes a first hydraulic pump for supplying a working fluid to the hydraulic motor, a second hydraulic pump for supplying a working fluid to the hydraulic motor for the lubricant pump, and a reservoir capable of storing the working fluid Wherein the flammable substance transporting device comprises: The method of claim 5,
The working fluid, stored in the reservoir,
Is supplied to the hydraulic motor through the first supply line after being pressurized by the first hydraulic pump, returns to the reservoir through the first return line,
Wherein the hydraulic fluid is supplied to the hydraulic motor for the lubricant pump through the second supply line after being pressurized by the second hydraulic pump and returns to the reservoir through the second return line. The method according to claim 1,
Wherein the working fluid used for driving the hydraulic motor is utilized as lubricating oil supplied for lubricating the hydraulic motor. Claims 1. A combustible material transfer device for an offshore structure used to transfer combustible material from one location to another in an offshore structure,
Pressurizing means for conveying the combustible material in one direction by pressurizing the combustible material;
A hydraulic motor for driving the pressing means;
Lubricating oil supply means for supplying lubricating oil to the hydraulic motor;
/ RTI >
The hydraulic motor is installed together in the same space as the pressing means,
The supply of the working fluid to the hydraulic motor and the supply of the lubricating oil to the hydraulic motor are performed by a dedicated hydraulic pressure generator,
Wherein the dedicated hydraulic pressure generator includes a first hydraulic pump for supplying a working fluid to the hydraulic motor, a second hydraulic pump for supplying lubricating oil to the hydraulic motor, and a reservoir capable of storing a working fluid,
Wherein the lubricating oil supply means is the second hydraulic pump. The method of claim 8,
The working fluid, stored in the reservoir,
The hydraulic motor is supplied to the hydraulic motor through the first supply line after being pressurized by the first hydraulic pump to return to the reservoir through the first return line,
Is supplied as lubricating oil to the hydraulic motor through the second supply line after being pressurized by the second hydraulic pump and returns to the reservoir through the second return line. delete delete The method according to claim 5 or 8,
Wherein the dedicated hydraulic pressure generating device includes two first hydraulic pumps in preparation for a malfunction. The method according to claim 1 or 8,
Wherein the pressurizing means is a pump or a compressor. The method according to claim 1 or 8,
Wherein the combustible material is compressed to 200 to 400 bara by the pressurizing means and then supplied as fuel to the MEGI engine. delete

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