KR20160000508U - Cargo reliquefaction apparatus of lpg ship - Google Patents

Abstract

The cargo res liquefying apparatus includes a frame integrally including a motor receiving sheet and a refueling element receiving sheet, the one end of which is protruded and accommodates the motor; A suction separator provided at an upper end of the reclosing element accommodating sheet for sucking and separating the fuel gas therein, a compressor connected to the motor and for compressing the separated fuel gas, Liquefied element enclosure for containing an accumulator for accumulating the re-liquefied fuel gas; And a partition disposed between the motor room and the compressor room. Therefore, the cargo liquefaction apparatus can perform the explosion-proof function by separating the motor room and the compressor chamber into the partition walls and arrange the constituent elements constituting the cargo liquefaction apparatus as close as possible. Further, each of the sheets can be integrally disposed in a common seat, and the cargo re-liquefying apparatus can be modularized to facilitate installation and disconnection on the LPG ship.

Description

{CARGO RELIQUEFACTION APPARATUS OF LPG SHIP}

The present invention relates to a cargo liquefaction technique, and more particularly, to a cargo liquefaction device modularized so as to be easily installed and separated on a liquefied petroleum gas ship.

The consumption of liquefied gas such as LNG (Liquefied Natural Gas) or 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 refueling concept of vaporizing gas is based on a closed N2 cycle that extracts heat from the vaporized gas. It becomes possible to re-liquefy the vaporized gas so that more liquefied gas can be detected by the gas consumer. The combination of the liquefied gas carrier and the refueling system of the vaporized gas increases the amount of cargo transported by the same vessel and significantly reduces the fuel cost for transportation. As a result, it is possible to lower the fares and secure safety.

Conventionally, since the main devices constituting the remelting device are disposed sporadically on separate sheets, not only the cargo line connecting them is long, but the arrangement itself is also not efficient. There was a lot of waste and scattered inefficiency of space arrangement. As a result, misalignment can occur frequently when the components of the cargo liquefaction device are connected, and quality can be degraded due to this problem.

In addition, all the equipment and components are installed for a long time (about 30 days) in the following stage during the manufacturing process of the ship, so that a lot of working time is required, and the working conditions for manufacturing the cargo liquefaction device may be lowered.

U.S. Patent No. 7,024,868 relates to Transportation of liquefied petroleum gas and discloses a pressure vessel for the transport of liquefied gas. U.S. Patent No. 8,381,544 discloses a method for liquefaction of natural gas and discloses a method for changing the calorific value of liquefied natural gas by adding a component having a high calorific value.

United States Patent No. 7,024,868 (Registered on April 11, 2006) United States Patent No. 8,381,544 (registered on February 26, 2013)

In one embodiment of the present invention, a motor room and a compressor room are divided into a bulkhead to perform an explosion-proof function.

One embodiment of the present invention seeks to arrange the main apparatuses constituting the liquefaction apparatus as close to the minimum holding space as possible.

One embodiment of the present invention is to provide an air trunk which can separate air circulation tanks to ensure an air circulation path and perform air purification without attaching a silencer.

One embodiment of the present invention seeks to assemble the components in a preceding stage to reduce the number of feeds of the following operations and to improve working conditions.

Among the embodiments, the cargo re-liquefying apparatus includes a frame integrally including a motor-receiving sheet and a refueling-element accommodating sheet, the motor-accommodating sheet being partly projected at one end thereof and accommodating the motor; A suction separator provided at an upper end of the reclosing element accommodating sheet for sucking and separating the fuel gas therein, a compressor connected to the motor and for compressing the separated fuel gas, A liquefied element enclosure for receiving a condenser for accumulating the re-liquefied fuel gas and an accumulator for accumulating the re-liquefied fuel gas; And a partition disposed between the motor room and the compressor room.

In one embodiment, the motor may correspond to an explosion-proof motor installed on the motor housing sheet and capable of preventing a fire or an explosion caused by an electrical or mechanical anomaly state.

In one embodiment, the cargo liquefaction device may include an economizer installed within the refueling element enclosure and providing the condensed fuel gas to the condenser.

In one embodiment, the suction separator is disposed on the partition wall side in the frame and can be connected to the compressor through the first pipe.

In one embodiment, the compressor is disposed on the opposite side of the partition in the suction separator, and may be coaxially connected with the motor in the frame and connected via the second pipe to the condenser.

In one embodiment, the economizer is disposed on the opposite side of the motor at the suction separator and is connected to the condenser through a third pipe and may be opposite the first end of the compressor.

In one embodiment, the condenser may be located on the opposite side of the partition in the suction separator and opposite the second end of the compressor.

In one embodiment, the accumulator is disposed in the direction of the suction separator in the condenser and may be connected to the condenser through a fourth pipe.

In one embodiment, the cargo liquefaction device may be modularized to be removable from a cargo pipe that is externally mounted and provides the fuel gas.

The disclosed technique may have the following effects. It is to be understood, however, that the scope of the disclosed technology is not to be construed as limited thereby, as it is not meant to imply that a particular embodiment should include all of the following effects or only the following effects.

The cargo liquefaction apparatus according to one embodiment of the present invention can perform an explosion-proof function by separating the motor room and the compressor room into the partition walls.

According to the embodiment of the present invention, the cargo liquefaction device can secure only the minimum holding space and can arrange the suction separator, the compressor, the economizer, the condenser, the accumulator and the motor as close as possible.

The cargo liquefaction device according to an embodiment of the present invention can integrate the respective sheets of the suction separator, the compressor, the economizer, the condenser, the accumulator, and the motor into one common sheet for modularization.

According to one embodiment of the present invention, it is possible to provide an air trunk which can separate air circulation tanks to secure an air circulation path and perform air purification without attaching a silencer.

According to one embodiment of the present invention, the assembling of the components in the preceding stages can be carried out in order to reduce the number of traversing operations and improve working conditions.

1 is a plan view showing a cargo liquefaction apparatus according to an embodiment of the present invention.
2 is a side view of the cargo liquefaction apparatus of Fig.
3 is a bottom view of the cargo liquefaction apparatus of Fig.
Fig. 4 is a view showing the components of the cargo re-liquefaction apparatus of Fig. 1. Fig.
Fig. 5 is a plan view showing a remanufacturing unit on which the cargo re-liquefying apparatus of Fig. 1 is mounted.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. However, the present invention may be embodied in many different forms and is not limited to the embodiments described herein. In the drawings, the same reference numerals are used throughout the specification to refer to the same or like parts.

FIG. 1 is a plan view showing a cargo liquefaction apparatus according to an embodiment of the present invention, FIG. 2 is a side view of the cargo liquefaction apparatus of FIG. 1, and FIG. 3 is a bottom view of the cargo liquefaction apparatus of FIG. 1 .

1 to 3, a cargo liquefaction apparatus 100 includes a frame 200, a motor 110, a suction separator 120, a compressor 130, a condenser 140, an accumulator 150, an economizer 160, a refueling element enclosure 170, and a partition 190.

The frame 200 integrally includes the motor-receiving sheet 210 and the refueling-element accommodating sheet 220. The motor receiving seat 210 protrudes from a part of one end of the refueling element receiving seat 220, and a motor 110 can be installed at the upper end thereof. The liquefied element accommodating sheet 220 can be provided with a liquefier element enclosure 170 at the top thereof and the liquefier element enclosure 170 is connected to the suction separator 120, the compressor 130, the condenser 140, the accumulator 150 and the economizer 160. [

The partition 190 may be installed between the motor-receiving sheet 210 and the refueling-element accommodating sheet 220. The motor 110 and the shaft 195 are installed on the upper side of the motor receiving seat 210 and the remelting element enclosure 170 can be installed on the upper side of the remelting element receiving sheet 220. The motor 110 may correspond to an explosion-proof motor that can prevent fire or explosion caused by an electrical or mechanical anomaly.

The motor 110 is installed at the upper end of the motor receiving seat 210 and connects the compressor 130 via the shaft 195 to transmit the power of the motor 110 to the compressor 130. More specifically, the motor 110 can receive power and rotate, and can transmit power generated on the shaft 195 of the motor 110 to the compressor 130. [

The suction separator 120 is installed on the upper side of the refueling element accommodating sheet 220 and is arranged on the side of the motor 110 in the frame 200. The suction separator 120 may be connected to the compressor 130 through the first pipe 181. The suction separator 120 may separate the flash gas from the fuel gas supplied from the cargo tank (not shown) and transfer the flash gas to the compressor 130 through the first pipe 181. Here, the fuel gas may include newly supplied fuel gas or re-liquefied fuel gas, and the flash gas may be generated when the condensed refrigerant liquid becomes less supercooled and enters the expansion side.

The compressor 130 may be installed on the upper side of the refueling element accommodating sheet 220 and disposed on the opposite side of the motor 110 in the suction separator 120. [ The compressor 130 may be coaxially connected to the motor 110 in the frame 200 and may be connected to the condenser 140 through the second pipe 182. [ Also, the compressor 130 may be connected to the economizer 160 via the third pipe 183. The compressor 130 can compress the fuel gas transferred from the suction separator 120 and transfer the compressed fuel gas to the condenser 140 or the economizer 160 through the second and third pipes 182 and 183 .

The condenser 140 is installed on the upper side of the refueling element accommodating sheet 220 and is disposed on the opposite side of the motor 110 in the suction separator 120 and can be opposed to the second end of the compressor 130. The condenser 140 may be connected to the economizer 160 via the fourth pipe 184 and may be connected to the accumulator 150 through the fifth pipe 185. The condenser 140 can re-liquefy the fuel gas transferred from the economizer 160 or the compressor 130 and transfer it to the accumulator 150 through the fifth pipe 185.

The accumulator 150 may be installed at the top of the refueling element accommodating sheet 220. The accumulator 150 can accumulate the re-liquefied fuel gas and release it as needed. More specifically, the accumulator 150 may be connected again through the suction separator 120 and the sixth pipe 186, and the accumulator 150 may transfer the discharged fuel gas to the suction separator 120. Accordingly, the suction separator 120 separates the transferred fuel gas and re-liquefies.

The economizer 160 may be installed on the upper side of the refueling element accommodating sheet 220 and may be disposed on the opposite side of the motor 110 from the suction separator 120. In addition, the economizer 160 may be opposite the first end of the compressor 130. The economizer 160 can expand the high-pressure refrigerant liquid at room temperature coming from the compressor 130 through the auxiliary expansion valve. More specifically, the economizer 160 can increase the refrigerating effect by supercooling the supplied refrigerant liquid. The fuel gas compressed by the compressor 130 is transferred to the condenser 140 through the fourth pipe 184 via the third pipe 183 via the economizer 160 or directly to the condenser 140 via the second pipe 182. [ 140, < / RTI > Various sensors or gauges may be installed at the connection between the suction separator 120, the compressor 130, the condenser 140, the accumulator 150 and the economizer 160.

In one embodiment, each sheet may be integrated into one common sheet. That is, each of the sheets may be arranged in one frame 200. More specifically, the motor 110 may be disposed in the motor receiving seat 210, and the suction separator 120, the compressor 130, the condenser 140, the accumulator 150, and the economizer 160 may be connected to the re- And may be disposed on the receiving sheet 220. As a result, the components 110 to 160 constituting the cargo resupplying apparatus 100 can be disposed as close as possible.

Liquefaction element enclosure 170 may be disposed at the top of refill liquor element receiving sheet 220. The re-liquefier element enclosure 170 includes a suction separator 120 for sucking and separating the fuel gas therein, a compressor 130 for compressing the separated fuel gas connected to the motor 110 and the shaft 195, An accumulator 150 for accumulating the re-liquefied fuel gas, and an economizer 160 for cooling the compressed fuel gas to provide it to the condenser.

Fig. 5 is a plan view showing a remanufacturing unit on which the cargo re-liquefying apparatus of Fig. 1 is mounted.

Referring to FIG. 5, the remanent unit 500 includes a motor room 510, a compressor room 520, and a cargo liquefaction apparatus 100.

The partition 190 separates the motor room 510 and the compressor room 520 from each other and can perform an explosion-proof function of the electric equipment used in the ship. For this reason, the motor 110 may correspond to an explosion-proof motor that performs an explosion-proof function. More specifically, the partition 190 can prevent a fire or an explosion caused by an electrical or mechanical anomaly of the motor 110. As a result, the cargo re-liquefier 100 may be provided with a partition 190 between the motor room 510 and the compressor room 520 to prevent fire or explosion caused by electrical or mechanical anomalies of the motor 110 .

In one embodiment, the remanufacturer 500 may include a total of four sets of cargo liquefier devices 100. In addition, the motor room 510 can receive the motor receiving seat 210, and the compressor room 520 can receive the refueling element receiving seat 220.

The cargo resurfacing device 100 can be disposed as close as possible to only the minimum maintenance space of the components 110 to 160. The respective components 110 to 160 constituting the cargo re-liquefier 100 can be connected through the pipes 181 to 186 to minimize the length of the cargo line. The components 110 to 160 of the cargo re-liquefaction apparatus 100 can be efficiently disposed, and the remanufacturing unit 500 can be neat.

The cargo res liquefier 100 may be modularized to be removable from a cargo pipe that is externally mounted and provides fuel gas. That is, the cargo re-liquefier 100 may be pre-assembled at a preceding stage during the manufacturing process of the ship. The preassembled cargo liquefaction apparatus 100 can be mounted (takes about 2 days) in the rear stage (dock) during the manufacturing process of the ship. More specifically, the components 110 to 160 constituting the cargo re-liquefaction apparatus 100 are not separately arranged in the following stage, and the respective components 110 to 160 are arranged in one frame 200 Can be integrated. As a result, the cargo liquefaction apparatus 100 can be modularized so as to be easily installed and separated on the LPG ship.

The re-culling unit 500 can be configured by mounting the cargo re-liquefying apparatus 100 on the following stage. The cargo re-liquefier 100 according to one embodiment of the present invention can be stocked after the test is completed in the preceding stage. Therefore, since there is little additional work in the following stage, the working time in the following stage can be shortened.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as set forth in the following claims And changes may be made without departing from the spirit and scope of the invention.

100: cargo re-liquefying device 110: motor
120: suction separator 130: compressor
140: condenser 150: accumulator
160: Economizer 170: Re-liquefied element enclosure
181: first pipe 182: second pipe
183: third pipe 184: fourth pipe
185: fifth pipe 186: sixth pipe
190: bulkhead 195: shaft
200: frame 210: motor receiving seat
220: Reclosing element accommodating sheet 500: Re-
510: Motor room 520: Compressor room

Claims (9)

A frame integrally including a motor-receiving sheet and a refueling-element accommodating sheet, the motor-accommodating sheet being partially projected at one end thereof;
A suction separator provided at an upper end of the reclosing element accommodating sheet for sucking and separating the fuel gas therein, a compressor connected to the motor and for compressing the separated fuel gas, Liquefied element enclosure for containing an accumulator for accumulating the re-liquefied fuel gas; And
A cargo liquefier comprising a bulkhead mounted between a motor room and a compressor room.
The motor drive apparatus according to claim 1, wherein the motor
And an explosion-proof motor provided on the motor-receiving sheet and capable of preventing a fire or an explosion caused by an electrical or mechanical abnormal condition.
The method according to claim 1,
And an economizer installed in the refueling element enclosure and cooling the compressed fuel gas to provide the condensed fuel to the condenser.
2. The apparatus of claim 1, wherein the suction separator
Wherein the frame is disposed on the partition wall side in the frame and connected to the compressor through a first pipe.
5. The compressor of claim 4, wherein the compressor
Wherein the suction pipe is disposed on an opposite side of the partition from the suction separator and is coaxially connected to the motor in the frame and connected to the condenser through a second pipe.
6. The system of claim 5, wherein the economizer
Wherein the suction pipe is disposed on an opposite side of the partition from the suction separator and is connected to the condenser through a third pipe and is opposed to the first end of the compressor.
6. The apparatus of claim 5, wherein the capacitor
And a second end of the compressor is disposed opposite to the partition in the suction separator.
8. The apparatus of claim 7, wherein the accumulator
Wherein the condenser is disposed in the direction of the suction separator in the condenser and is connected to the condenser through a fourth pipe.
The method according to claim 1,
And is modularized so that it can be separated from a cargo pipe provided outside and providing the fuel gas.

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