KR200491857Y1 - Pump device for gas carrier - Google Patents

Abstract

The disclosure disclosed herein relates to the provision of a pump device for effectively receiving and driving a driving force of a driving part through a partition formed between a driving part and a pump disposed in different spaces.
According to one embodiment of the contents disclosed in the present specification, the pump device is a driving unit, a hydraulic pump formed to be connected to and driven by a driving shaft of the driving unit, a hydraulic motor connected to the hydraulic pump and driven through the hydraulic pump, and the hydraulic motor It includes a pump formed to be connected to the drive shaft of the drive, the pump pumps the liquid containing the liquefied gas flowing through the drive to the outside.

Description

Pump device for gas carrier {PUMP DEVICE FOR GAS CARRIER}

The disclosure disclosed herein relates to a pump, and more particularly, to a pump device for pumping liquefied gas containing LNG and LPG carried by a gas carrier to transport the liquefied gas.

Unless otherwise indicated herein, the content described in this section is not prior art to the claims of this application and is not admitted to be prior art by inclusion in this section.

As shown in FIG. 1, the carrier 1 for transporting liquefied gas containing LNG and LPG is external to the liquefied gas in the tank 7 for storing the liquefied gas transported through the pump 3 of the pump device. Move to or inject liquefied gas toward the tank (7).

However, the pump 3 for pumping flammable liquefied gas is connected in a separated state through a motor 2 driven by electric power and a partition 4 and a sealing 5 to prevent a fire or accident. There is a disadvantage that this is required and a seismic isolation device is required separately.

Therefore, there is a need for a technology that reduces the installation cost and fire occurrence of a pump device installed inside the carrier 1 and used to transport liquefied gas to the outside or inject it into the interior of the tank 7.

In this regard, Korean Patent Registration No. 10-1312039 discloses a pump for LNG, and Korean Patent Publication No. 10-1687450 discloses a cryogenic high pressure pump for transporting LNG.

However, the existing inventions do not disclose the technology of a pump device that can be quickly installed with the pump and motor separated.

Korean Registered Patent Publication No. 10-1312039 Korean Registered Patent Publication No. 10-1687450

It is to provide a pump device for effectively receiving and driving the driving force of the driving part through a partition wall formed between the driving part and the pump disposed in different spaces.

In addition, it is obvious that other technical problems may be derived from the following description, not limited to the technical problems as described above.

According to one embodiment of the disclosed contents, the pump device includes a driving unit, a hydraulic pump formed to be connected to and driven by the driving unit, a hydraulic motor connected to the hydraulic pump and driven through the hydraulic pump, and a driving shaft of the hydraulic motor It includes a pump formed to be connected and driven, and the pump pumps a liquid containing liquefied gas flowing through the drive to the outside.

In addition, the pump device is connected to the hydraulic pump and the other end through the partition wall in the state where the hydraulic pump and the hydraulic motors are arranged in different spaces with the partition wall therebetween, and the other end penetrates the partition wall to further connect the hydraulic motor. It can contain.

In addition, the pump may be connected to a shaft and a cam connected to a drive shaft of the hydraulic motor to pump the liquid injected into the cylinder through a piston moving up and down in a cylinder toward the top of the cylinder.

In addition, the pump is connected to the upper portion of each of the plurality of cylinders and includes a discharge pipe extending toward the outlet outside the pump, and the liquid corresponds to a position spaced apart from the outlet through the cylinders and pistons The discharge pipe may be sequentially introduced into the discharge pipe from the discharge pipe to the discharge pipe corresponding to a position adjacent to the discharge port.

In addition, the pump may further include a backflow prevention valve formed to prevent backflow of the liquid toward each of the cylinders between each of the cylinders and the discharge pipe.

In addition, the pump device may further include a connection part made of a flexible shaft that is connected to a drive shaft of the driving part and the other end passes through a partition wall blocking between the drive part and the hydraulic pump and is connected to the drive shaft of the hydraulic pump.

According to one embodiment disclosed in the present specification, the pump device is capable of effectively transmitting the driving force of the driving units disposed in different spaces through the partition wall to the pump and transmitting the driving force to the pump through hydraulic pressure, thereby reducing installation cost and time. There is this.

In addition, the pump device is provided with a connection between the hydraulic pump and the hydraulic motor connected to each of the drive unit and the pump is disposed in a space separated from each other with a partition wall therebetween, it is easy to install the connection regardless of the position of the drive unit and pump There are advantages.

In addition, since the effects of the present invention described as described above are naturally exerted by the composition of the contents regardless of whether the inventor recognizes them or not, the above-described effects are only a few effects according to the contents described, and all effects that the designer grasps or exists. It should not be admitted that it is written.

In addition, the effect of the present invention should be further understood by the overall description of the specification, even if it is not described in an explicit sentence, those skilled in the art to which the described content belongs may have such an effect through this specification. If it can be recognized as an effect, it should be regarded as the effect described in this specification.

1 is a cross-sectional view showing a conventional pump device.
Figure 2 is a perspective view showing a pump device according to an embodiment of the content disclosed herein.
3 is a perspective view of the pump device of FIG. 2 when viewed from another angle.
Figure 4 is a cross-sectional view taken along line I-I' of Figure 3;
5 is a perspective view showing a pump device according to another embodiment of the contents disclosed herein.

Hereinafter, the configuration, operation and effect of the pump device according to the preferred embodiment will be described with reference to the accompanying drawings. For reference, in the following drawings, each component is omitted or schematically illustrated for convenience and clarity, and the size of each component does not reflect the actual size, and the same reference numerals refer to the same components throughout the specification. Reference numerals for the same components in the individual drawings will be omitted.

Figure 2 shows a perspective view showing a pump device according to an embodiment of the content disclosed herein. 3 shows a perspective view of the pump device of FIG. 2 from a different angle. FIG. 4 shows a cross-sectional view taken along line I-I' of FIG. 3.

2 to 4, the pump device 100 includes a driving unit 200, a hydraulic pump 300, a connecting portion 350, a hydraulic motor 400 and a pump 500.

The pump device 100 pumps the driving force of the driving unit 200 installed to be separated into a different space from the pump 500 through the partition wall 10 and the upper and lower decks through the hydraulic pump 300 and the hydraulic motor 400. ) Has the advantage of reducing installation time and cost.

The pump device 100 transfers the liquefied gas stored inside the tank 7 carried by the transport line 1 through the pumping drive to the outside along the transport unit 600, or liquefied from the transport unit 600 Gas is introduced into the interior of the tank (7).

Specifically, the driving unit 200 is disposed in a space formed on one side of the partition wall 10, and the driving shaft of the driving unit 200 extends a predetermined distance toward the partition wall 10 and is connected to the driving shaft of the hydraulic pump 300. .

The driving unit 200 includes a motor operating through electric power, an engine operating through hydrogen energy or fossil fuel, and a hydraulic pump 300 connected through driving of the driving unit 200 operates.

The hydraulic pump 300 is connected to the drive shaft of the driving unit 200 to transfer the oil inside to the hydraulic motor 400 through the connection unit 350 by driving the driving unit 200, and the hydraulic motor 400 is the oil It is driven by the pressure of the pump 500 to transmit the driving force.

The connection part 350 includes a first connection pipe 352 and a second connection pipe 354.

One end of the connecting portion 350 is connected to the hydraulic pump 300 at one side of the partition wall 10, the other end is connected to the hydraulic motor 400 through the partition wall 10, discharged through the pumping of the hydraulic pump 300 The oil to be transferred to the hydraulic motor 400.

One end of the first connection pipe 352 is connected to the oil outlet formed in the hydraulic pump 300 and coupled with the hydraulic pump 300, the other end passing through the partition wall 10 is formed on the outside of the hydraulic motor 400 It is connected to the oil injection port and is connected to the hydraulic motor 400.

One end of the second connection pipe 354 is connected to the oil inlet formed in the hydraulic pump 300 and coupled with the hydraulic pump 300, the other end passing through the partition wall 10 is formed on the outside of the hydraulic motor 400 It is connected to the oil outlet and is connected to the hydraulic motor (400).

A portion of the outer surface of each of the first and second connecting pipes 352 and 354 penetrating the partition wall 10 is formed with a sealing member so that liquefied gas flowing out from the pump 500 located on the other side of the partition wall 10 is partition wall (10) is blocked from flowing into one side.

The hydraulic motor 400 is disposed in the other space of the partition wall 10, the other end of each of the first and second connecting pipes 352 and 354 is coupled to each of the oil inlet and oil outlets, and the hydraulic pump 300 ) To rotate the drive shaft formed on the other side.

The pump 500 includes a shaft 505, first to third cams 510, 520, 530, first to third connecting rods 512, 522, 532, first to third pistons 514, 524, 534, including first to third cylinders 516, 526, 536 and first to third valves 518, 528, 538.

The pump 500 pumps the liquefied gas flowing through the inlet pipe 20 to which the tank 7 or the transfer unit 600 is connected, and then the transfer unit 600 or the tank 7 through the outlet 42 formed on the outside. Move towards.

Specifically, one end of the shaft 505 is connected to the drive shaft of the hydraulic motor 400 and the other end extends a predetermined distance toward the other side of the partition wall 10 and rotates by the drive shaft of the hydraulic motor 400.

Each of the first to third cams 510, 520, and 530 is formed on the shaft 505 to be spaced apart from each other at a predetermined distance along the extending direction of the shaft 505 from one end to the other end of the shaft 505.

The first cam 510 is formed at a position close to the inlet pipe 20 adjacent to one end of the shaft 505, and is formed to extend in a direction perpendicular to the extending direction of the shaft 505 in the form of'c'.

When the second cam 520 is viewed from one end of the shaft 505 at a position spaced apart by a predetermined distance along the extending direction of the shaft 505 from the first cam 510, the second cam 520 is more predetermined than the first cam 510. It is formed in a state rotated counterclockwise by an angle.

When the third cam 530 is viewed from one end of the shaft 505 at a position spaced apart by a predetermined distance along the extending direction of the shaft 505 from the second cam 520, the third cam 530 is more predetermined than the second cam 520. It is formed in a state rotated counterclockwise by an angle.

One end of the first connecting rod 512 is coupled to the first cam 510 so as to be rotatable, and the other end extends toward the upper portion and slides upward or downward from the inside of the first cylinder 516 The piston 514 is coupled to enable rotation.

One end of the second connecting rod 522 is coupled to the second cam 520 so as to be rotatable, and the other end extends toward the top and slides toward the top or bottom from the inside of the second cylinder 526 The piston 524 is coupled to enable rotation.

One end of the third connecting rod 532 is coupled to the third cam 530 so as to be rotatable, and the other end extends toward the top and slides toward the top or bottom from the inside of the third cylinder 536 The piston 534 is coupled to enable rotation.

The first to third cylinders 516, 526, and 536 are formed with pipe-like passages connected to the discharge pipe 40 located at the upper portion of each of the first and third cylinders 516, 526, and 536, respectively. Each of the first to third valves 518, 528, and 538, which control the movement of the liquefied gas discharged upward from the inside of each of the 526, 536, is formed.

Each of the first to third valves 518, 528, and 538 prevents reverse flow in which liquefied gas can only move in one direction toward the discharge pipe 40 inside each of the first to third cylinders 516, 526, and 536. It is formed as a valve.

Accordingly, the liquefied gas injected into each of the first to third cylinders 516, 526, and 536 is first to third through sequential elevation of each of the first to third pistons 514, 524, and 534. 3 valves (518, 528, 538) passes through each of the discharge pipe (40).

The liquefied gas injected into the discharge pipe 40 is injected into the discharge pipe 40 by the sequential pressure of each of the first to third pistons 514, 524, and 534, so that the liquefied gas injected by the first piston 514 Moves smoothly toward the outlet 42 together with the liquefied gas injected through each of the second and third pistons 524 and 534.

Meanwhile, the partition wall 10 may be connected to a separate case formed in a form surrounding the driving unit 200 to block a space in which the driving unit 200 is disposed from a space in which the pump 500 is disposed.

5 shows a perspective view of a pump device according to another embodiment of the content disclosed herein.

Since the pump device 120 according to the present embodiment is substantially the same as the pump device 100 of FIGS. 1 to 4 except for the connecting portion 370, the same reference numbers and names are used, and duplicate descriptions are omitted.

As shown in FIG. 5, the pump device 120 includes a connection portion 370.

The pump unit 120 is connected to the drive shaft of the drive unit 200 and the drive shaft of the hydraulic pump 300 through a flexible shaft (Flexible shaft), the drive unit 200 disposed in different spaces with the partition wall 10 therebetween, and Even if the installed height of each of the pumps 500 is different or is arranged at an angle to each other, it is easy to transmit the driving force.

The connection portion 370 is manufactured through a flexible shaft, and one end is connected to the drive shaft of the drive unit 200 and the other end is connected to the drive shaft of the hydraulic pump 300 through the partition wall 10.

Therefore, when the driving unit 200 is driven, the connection unit 370 transmits a driving force to the drive shaft of the hydraulic pump 300, and the hydraulic motor 400 and the pump 500 operate by the operation of the hydraulic pump 300 to operate the pump ( 500) The liquid gas flowing inside is discharged to the outside.

In addition, since only a single connecting portion 370 penetrates the partition wall 10 and is connected to the hydraulic pump 300, a part of liquefied gas leaks from the pump 500 and flows through the partition wall 10 to the driving unit 200. Can be effectively prevented.

As another embodiment, the pump device 140 is substantially the same as the pump device 120 of FIG. 5 except for the driving part 220, the connecting part 700, and the gear part 800, as shown in an enlarged manner. The same reference number and name are used and duplicate description is omitted.

The pump device 140 includes a driving part 220, a connecting part 700, and a gear part 800.

The pump device 140 closely connects the flexible shafts connected to each of the plurality of motors, and then inserts them into the inside of a single sealing member in the form of a pipe penetrating the partition wall 10, and a gear part connected to one side of the hydraulic pump 300 It is formed to connect to 800.

The pump device 140 effectively transmits the power of the plurality of motors to the hydraulic pump 300 through the plurality of flexible shafts and the gear unit 800 to enable smooth driving of the hydraulic pump 300.

Specifically, the driving unit 220 includes motors 230, 240, and 250, and the connecting unit 700 includes first to third shafts (each of the driving shafts of the motors 230, 240, 250 and one end of which are connected) 710, 720, 730).

The other end of each of the first to third shafts 710, 720, and 730 extends toward the hydraulic pump 300 through a pipe-shaped sealing member passing through the partition wall 10 and is connected to the gear part 800.

The gear part 800 is a first gear to a third gear 820 connected to the other end of each of the drive gear 810 and the first to third shafts 710, 720, and 730 connected to the drive shaft of the hydraulic pump 300 , 830, 840).

The driving gear 810 is coupled to the driving gear of the hydraulic pump 300 on the other side of the hydraulic pump 300, and the first to third gears 820, 830, and 840 are each spaced apart from each other. It is arranged in a form surrounding the outside of 810) to engage the drive gear 810.

One side of each of the first to third gears 820, 830, and 840 located on the other side of the other side coupled to the connecting portion 700 is coupled to be rotatable in a separate case surrounding the gear portion 800 .

Accordingly, the first to third gears 820, 830, and 840 rotate by driving each of the first to third shafts 710, 720, and 730, thereby rotating the driving gear 810 and driving gear 810. Drives the hydraulic pump 300.

On the other hand, the sealing member surrounding the first to third shafts 710, 720, and 730 penetrating the partition wall 10 is a first to form a shape surrounding each of the first to third shafts 710, 720, 730. To the third shaft (710, 720, 730) is in close contact with the outer surface of each can effectively prevent the outflow of liquefied gas.

The preferred embodiments of the present invention have been described above with reference to the accompanying drawings, but the embodiments described in the specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention and represent all technical ideas of the present invention. It should be understood that there may be various equivalents and modifications that can replace them at the time of application. Therefore, the embodiments described above are illustrative in all respects and should be understood as non-limiting, and the scope of the present invention is indicated by the following claims rather than the detailed description, and the meaning and scope of the utility model claim and It should be construed that any altered or modified form derived from the equivalent concept is included in the scope of the present invention.

100, 120, 140: pump unit 200, 220: drive unit
300: hydraulic pump 350, 370, 700: connection
400: hydraulic motor 500: pump
600: transfer unit 800: gear unit

Claims (6)

Drive unit;
A hydraulic pump formed to be driven in connection with the drive shaft of the driving unit;
A hydraulic motor connected to the hydraulic pump and driven through the hydraulic pump;
A pump formed to be connected and driven with a drive shaft of the hydraulic motor; And
One end is connected to the drive shaft of the drive unit, the other end is a connection unit made of a flexible shaft connected to the drive shaft of the hydraulic pump through a partition wall blocking between the drive unit and the hydraulic pump; includes,
The pump is a pump device characterized in that to pump the liquid containing the liquefied gas flowing through the drive to the outside.
According to claim 1,
In the state in which the hydraulic pump and the hydraulic motors are arranged in different spaces with a partition wall therebetween, one end is connected to the hydraulic pump and the other end passes through the partition wall and is connected to the hydraulic motor. Pump device.
According to claim 1, The pump,
A pump device characterized by pumping the liquid injected into the cylinder through a piston connected to a shaft and a cam connected to a drive shaft of the hydraulic motor and moving up and down in a cylinder toward an upper portion of the cylinder.
According to claim 3, The pump,
A discharge pipe connected to the upper portion of each of the plurality of cylinders and extending toward the outlet outside the pump,
The liquid is pumped through the cylinders and pistons, characterized in that sequentially flows into the discharge pipe from the discharge pipe corresponding to the position spaced apart from the discharge port to the discharge pipe corresponding to the position adjacent to the discharge port.
According to claim 4, The pump,
And a backflow prevention valve formed between each of the cylinders and the discharge pipe to prevent backflow of the liquid toward each of the cylinders.
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