KR101313186B1 - Pump tower - Google Patents

Abstract

The pump tower is disclosed. The pump tower of the present invention includes a main body for loading and unloading liquefied natural gas into a cargo tank for storing liquefied natural gas (LNG); Cone base coupled to the bottom of the cargo tank; A first divided low mast unit coupled to the cone base; A second divided low mast unit coupled to the first divided low mast unit; And a plurality of upper mast units that are pre-coupled to the second divided low mast unit before the first divided low mast unit and the second divided low mast unit are coupled to each other.

Description

Pump Tower {PUMP TOWER}

The present invention relates to a pump tower, and more particularly, a gas carrier carrying a liquefied natural gas (Liquefied Natural Gas, LNG), a floating offshore structure (LNG-FPSO, LNG-FSRU) and LNG. The present invention relates to a pump tower for loading or unloading liquefied natural gas (LNG) in a cargo tank such as a regasification vessel (LNG-RV).

Natural Gas (NG) typically takes up much less volume in the liquefied state than in the gaseous state, so it is designed to transport or store them, such as gas carriers and floating offshore structures (LNG-FPSO, LNG-FSRU). Cargo tanks installed in LNG regasification vessels (LNG-RV) are maintained at high pressure and low temperature to prevent vaporization of liquefied gas.

Cargo tanks of the high pressure and low temperature state are installed with a pump tower (Load Tower) for loading or unloading the liquefied natural gas.

The upper side of the pump tower is welded to the liquid dome cover of the cargo tank and the lower side is supported by a pump tower support fixed to the bottom of the cargo tank. Prior art related to such a pump tower is disclosed in Korean Patent Publication No. 10-2010-0103266 (2010.09.27) "pump tower".

In general, the pump tower includes a loading pipe for loading liquefied natural gas into the cargo tank, and a discharge pipe for discharging liquefied natural gas stored in the cargo tank to the outside of the cargo tank. And a base plate disposed under the pump tower to support lower ends of the loading pipe and the discharge pipe, respectively.

The pump tower further includes a mast guide that is partially coupled to the base plate and guides a stripping pump to pump liquefied natural gas out of the cargo tank.

Pump tower PT according to a conventional embodiment having the above-described configuration is coupled to the bottom of the cargo tank (T) in the order shown in FIG.

Specifically, first, the pump tower support 10 is welded to the bottom of the cargo tank (T), as shown in Figure 1 (a). Thereafter, the pump tower PT is mounted on the pump tower support 10, as shown in FIG.

Next, the mast guide 20 is welded to the base plate BP and the pump tower support 10, respectively, and a pump seat unit (not shown) is coupled to the mast guide 20, and then a stripping pump (not shown) is provided to the pump seat unit. To complete the work.

The conventional embodiment described above has a disadvantage in that the work is inconvenient and the working efficiency is lowered because the mast guide, the pump seat unit, and the stripping pump are installed in a narrow work space after the pump tower is installed at the bottom of the cargo tank.

In addition, the mast guide can be combined only by a welding method that can work even in a narrow work space. Welding is performed in a narrow work space, so even a skilled technician may cause a welding failure.

In addition, when welding failure occurs in the welding surface of the mast guide, the stripping pump may be shaken or dislodged during the pumping of the liquefied natural gas, thereby delaying the work, and in severe cases, may cause human injury due to the characteristics of the cryogenic liquefied natural gas.

Korean Patent Publication No. 10-2010-0103266 (Samsung Heavy Industries Co., Ltd.) 2010. 09. 27

Therefore, the technical problem to be achieved by the present invention is to provide a pump tower that can solve the problem that work is performed in a narrow working space, which is the biggest problem in the installation of a conventional pump tower, work efficiency is lowered and welding defects may occur. It is.

According to an aspect of the present invention, a body for loading and unloading liquefied natural gas into an interior of a cargo tank for storing liquefied natural gas (LNG); A cone base coupled to the bottom of the cargo tank; A first divided low mast unit coupled to the cone base; A second divided low mast unit coupled to the first divided low mast unit; A pump tower may include a plurality of upper mast units that are pre-coupled to the second divided low mast unit before the first divided low mast unit and the second divided low mast unit are coupled to each other.

 The upper mast unit and the second divided low mast unit may be bolted to each other.

The second divided low mast unit may include: a second divided low mast body coupled to the first divided low mast unit; And a plurality of upper mast mounting portions coupled to the second divided low mast body and to which the plurality of upper mast units are fixed.

The upper mast unit, the upper mast body; And a pad module coupled to one side of the upper mast mounting portion and the other side coupled to the upper mast body to allow a relative vertical flow between the upper mast body and the upper mast mounting portion by a predetermined distance.

The pad module may include: a pad support plate coupled to the upper mast body and provided with a pad installation groove on a surface opposite the upper mast mounting portion; And a pad installed in the pad installation groove.

The upper mast unit may further include a stopper coupled to the upper mast body to prevent the pad module from being pushed.

The pad support plate and the upper mast body may be bolted to each other.

The pad support plate, the plate-shaped support plate body; And a pair of wings protruding from the support plate body, wherein the stopper is welded to the upper stopper body to support the wings.

It may further include a pump seat unit coupled to the second divided low mast unit before the second divided low mast unit is coupled to the first divided low mast unit.

It may further include a stripping pump mounted on the pump seat unit.

It may further include a stripping pump mounted to the pump seat unit for unloading the liquefied natural gas in the cargo tank.

Embodiments of the present invention can improve the work efficiency and prevent the occurrence of welding defects by solving the problem that work is performed in a narrow work space which is the biggest problem in the conventional pump tower installation.

1 is a view schematically showing a state in which the lower portion of the pump tower according to an embodiment of the prior art is installed in the cargo tank.
2 is a view schematically showing a pump tower according to an embodiment of the present invention.
3 is a plan view illustrating a state in which a plurality of upper mast units are coupled to a second divided low mast unit in the pump tower illustrated in FIG. 2.
4 is an exploded perspective view of the upper mast unit shown in FIG. 3.
5 is a plan view illustrating a coupled state of the upper mast unit shown in FIG. 4.
6 is a perspective view illustrating a state in which a plurality of upper mast units and a pump seat unit are coupled to a second divided low mast unit.

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the accompanying drawings which illustrate preferred embodiments of the present invention.

Hereinafter, the present invention will be described in detail with reference to the preferred embodiments of the present invention with reference to the accompanying drawings. In the following description, well-known functions or constructions are not described in order to avoid unnecessary obscuration of the present invention.

FIG. 2 is a view schematically illustrating a pump tower according to an embodiment of the present invention, and FIG. 3 is a view illustrating a state in which a plurality of upper mast units are coupled to a second divided low mast unit in the pump tower shown in FIG. 2. 4 is an exploded perspective view of the upper mast unit illustrated in FIG. 3, and FIG. 5 is a plan view illustrating a coupled state of the upper mast unit illustrated in FIG. 4.

As shown in these figures, the pump tower 1 according to the present embodiment, loading the liquefied natural gas into the cargo tank (Cargo Tank, not shown) for storing the liquefied natural gas (LNG) and Unloading main body 100, the cone base 200 coupled to the bottom of the cargo tank, the first divided low mast unit 300 coupled to the cone base 200, the first divided low mast The second divided low mast unit 400 coupled to the unit 300 and the second divided low mast unit 400 before the first divided low mast unit 300 and the second divided low mast unit 400 are coupled to each other. ) Is provided with a plurality of upper mast units 500 which are preliminarily coupled to the upper and lower sides.

As shown in FIG. 2, the main body 100 includes a loading pipe 110 for loading liquefied natural gas into the cargo tank, and a cargo tank for storing the liquefied natural gas stored in the cargo tank. In order to discharge the liquefied natural gas to the outside in the event of a failure of the pair of discharge pipes (120, Discharge Pipe) and the stripping pump 700 for discharging the liquefied natural gas through the discharge pipe 120 An emergency pump well 130 and a base plate disposed below the loading pipe 110 and the pair of discharge pipes 120 to support lower ends of the loading pipes 110 and the discharge pipes 120, respectively. 140.

The base plate 140 of the main body 100 may be formed in a triangular plane shape to stably support the loading pipe 110, the pair of discharge pipes 120, and the emergency pump well 130. And the loading pipe 110 is disposed adjacent to the emergency pump well 130, is connected to an external loading device (not shown) to load the liquefied natural gas into the cargo tank.

Cone base 200 is, prior to the installation of the main body 100 is coupled to the bottom of the cargo tank as the top priority, the lower cone 210 and the lower side can be coupled to the bottom of the cargo tank in the manner of welding coupling, the lower The first plate 220 is coupled to the upper side of the cone 210, the upper cone 230 is coupled to the upper side of the first plate 220 but smaller than the lower cone 210 and the upper cone 230 It is coupled to the upper side of the includes a second plate 240 is formed in a smaller size than the first plate (220).

In the present embodiment, as shown in FIG. 2, the cone base 200 is made smaller in size from the lower side to the upper side and formed in a multi-layer, which is relatively extremely high load disposed on the upper side of the cone base 200. In order to support the body 100 without being damaged.

Although the first divided low mast unit 300 forms one body with the second divided low mast unit 400 to be described later, the first divided low mast unit 300 is separated from the second divided low mast unit 400 when the pump tower 1 according to the present embodiment is installed. It is coupled to the upper surface of the second plate of the cone base 200 by a welding coupling method, and is coupled to the bottom of the cargo tank with the cone base 200 before the main body 100.

As shown in FIG. 2, the second divided low mast unit 400 is first coupled to the bottom of the base plate 140 by the upper mast unit 500 to be described later, and then the first divided low mast. It is coupled to the unit 300 by a welding coupling method serves to connect the main body 100 and the cone base 200.

In the present embodiment, the second divided low mast unit 400 may be formed in a cylindrical shape, as shown in FIG. 3, and the second divided low mast body coupled to the first divided low mast unit by a welding coupling method ( 410 and a pair of upper mast mounting portions 420 respectively coupled to both sides of the second divided low mast body 410 and to which the plurality of upper mast units 500 are fixed.

A plurality of fastening holes 420a are formed in the upper mast mounting part 420 of the second divided low mast unit 400 so that the upper mast unit 500 may be bolted to each other.

Since the upper mast unit 500 is coupled to the second divided low mast unit 400 before the main body 100 is fixed to the bottom of the cargo tank unlike the conventional embodiment, the upper mast unit ( Combination work of 500) is not made can be convenient to combine work.

In addition, since the coupling operation of the upper mast unit 500 in the present embodiment is not made in a narrow working space, the upper mast unit 500 and the second divided low mast unit 400 may be bolted in addition to the welding coupling method as in the related art. It may be combined in a manner of bonding.

As a result, the upper mast unit 500 and the second divided low mast unit 400 may be coupled in a relatively convenient bolt coupling method rather than a welding coupling method, and thus, the operation is convenient and will be described in detail later. Pad 540 disposed between the two divided low mast unit 400 also has the advantage that it can be easily replaced.

Now, the upper mast unit 500 will be described in detail. The upper mast unit 500 has one side coupled to the upper mast body 510 and the upper mast mounting unit 420 as shown in FIG. The pad module 520 is coupled to the upper mast body 510 to allow a relative distance between the upper mast body 510 and the upper mast mounting part 420 by a predetermined distance.

The upper mast body 510 of the upper mast unit 500 may be formed in different shapes, as shown in FIG. 3. Specifically, the upper mast body 510 coupled to the horizontal direction of the second divided low mast unit 400 has a stronger structure than the upper mast body 510 coupled to the longitudinal direction of the second divided low mast unit 400. The space may be formed by the barrier rib.

Meanwhile, the upper mast body 510 may be coupled to the upper side of the upper mast body 510 by a welding coupling method.

As shown in FIGS. 4 and 5, the pad module 520 of the upper mast unit 500 is coupled to the upper mast body 510 and is disposed on a surface opposite to the upper mast mounting portion 420. ) Is provided with a pad support plate 530, and a pad 540 is installed in the pad installation groove (531a).

As shown in FIG. 3, the pad support plate 530 of the pad module 520 is bolted to the upper mast mounting portion 420 and bolted to the upper mast body 510 on the other side.

In the present exemplary embodiment, the pad support plate 530 disposed in the horizontal direction of the second divided low mast unit 400 may be bolted to the upper mast mounting part 420 as shown in FIG. The pad support plate 530 disposed in the longitudinal direction of the split low mast unit 400 may be disposed to contact the upper mast mounting unit 420 in a free state without being coupled to the upper mast mounting unit 420.

The pad support plate 530 is in a free state without being coupled to the upper mast mounting portion 420. The pad support plate 530 is bolted to the upper mast body 510 and the upper mast body 510. ) Is welded to the base plate 140, so there is no problem even if the pad support plate 530 is not coupled to the upper mast mounting portion 420. This is to ensure that the flow occurs smoothly.

Relative up and down flow between the upper mast body 510 and the upper mast mounting portion 420 is caused by the contraction action between the components due to the cryogenic environment characteristics, such a contraction range is about 80mm.

Meanwhile, as shown in FIG. 4, the pad support plate 530 protrudes from the plate-shaped support plate body 531 having the pad installation groove 531 a formed on one side thereof, and the upper plate body 531. The wing portion 532 is bolted to the 510 (see FIG. 5) and one side is welded to the back of the support plate body 531 and the other side is welded to the wing 532 so that the wing 532 is It includes a reinforcing material (533) to be firmly fixed to the support plate body (531).

In this embodiment, the pad support plate 530 is coupled to the above-mentioned upper mast body 510 by a bolt coupling method, which serves to facilitate replacement of the pad 540 installed in the pad installation groove 531a. .

Specifically, the pad 540 is disposed between the upper mast body 510 and the upper mast mounting part 420 to prevent direct contact between the upper mast body 510 and the upper mast mounting part 420. When the life is over and needs to be replaced, the pad 540 may be loosened by loosening the bolt between the pad support plate 530 and the upper mast body 510 and by loosening the bolt between the pad support plate 530 and the upper mast mount 420. It can be replaced conveniently.

In the present embodiment, the reinforcement 533 of the pad support plate 530 may be a plate having a triangular plane shape, as shown in FIG. 5.

Meanwhile, the upper mast unit 500 further includes a stopper 550 coupled to the upper mast body 510 to prevent the pad module 520 from being pushed.

In this embodiment, the stopper 550 may be disposed to contact the wing 532 of the pad support plate 530 and may be coupled to the upper mast body 510 by welding.

6 is a perspective view illustrating a state in which a plurality of upper mast units and a pump seat unit are coupled to a second divided low mast unit.

In this embodiment, before the second divided low mast unit 400 is coupled to the first divided low mast unit 300, the second divided low mast unit 400 is coupled to one side of the stripping pump pipe support 610. The pump seat unit 600 and a stripping pump 700 mounted on the pump seat unit 600 to unload the liquefied natural gas in the cargo tank further includes.

In one embodiment of the prior art, the pump tower unit and the stripping pump are mounted after the pump tower is fixed to the bottom of the cargo tank. This mounting work takes many working days because the work is performed in a narrow working space.

On the contrary, in the present embodiment, since the pump seat unit 600 and the stripping pump 700 are pre-mounted on the upper mast unit 500, the work day is reduced by about 2 days compared to the conventional embodiment.

Hereinafter, the installation process of the pump tower according to the present embodiment will be described schematically.

First, the cone base 200 on which the first split low mast unit 300 is fixed is welded to the bottom of the cargo tank.

Next, the upper mast unit 500 is coupled to the base plate 140 and the second divided low mast unit 400 of the main body 100, respectively. Specifically, the upper mast body 510 upper portion of the upper mast unit 500 is welded to the lower side of the base plate 140, the pad module 520 of the upper mast unit 500 is optional to the upper mast mounting portion 420 Bolted together.

Next, the pump seat unit 600 is coupled to the upper mast unit 500, and the stripping pump 700 is mounted to the pump seat unit 600. The pump seat unit 600 and the stripping pump 700 may be pre-coupled to the upper mast unit 500 before the upper mast unit 500 is coupled to the base plate 140 and the second divided low mast unit 400. It may be.

Finally, the first divided low mast unit 300 and the second divided low mast unit 400 are welded to finish the work.

In the present embodiment, since the upper mast unit 500, the pump seat unit 600, the stripping pump 700, and the like are combined in a large space, the work can be shortened by about 10 days compared to the conventional embodiment. There is an advantage.

In addition, since the upper mast unit 500 is coupled to the second divided low mast unit 400 in a large working space by a bolt coupling method, defects such as welding defects do not occur as in the conventional exemplary embodiment.

Furthermore, since the pad support plate 530 is coupled to the upper mast body 510 in a bolted manner, the pad support plate 530 and the upper mast body 510 when the pad 540 reaches the end of its life and need to be replaced. When the bolt is coupled to the pad support plate 530 and the bolt coupling between the upper mast mounting portion 420, the pad 540 may be conveniently replaced.

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 or scope of the invention. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

1: pump tower 100: body
110: loading pipe 120: discharge pipe
130: emergency pump well 140: base plate
200: cone base 300: first divided low mast unit
400: second divided low mast unit 410: second divided low mast body
420: upper mast mounting portion 500: upper mast unit
510: upper mast body 520: pad module
530: pad support plate 540: pad
550: stopper 600: pump seat unit
610: stripping pump pipe support 700: stripping pump
T: cargo tank

Claims (10)

A main body for loading and unloading the liquefied natural gas into a cargo tank storing the liquefied natural gas (LNG);
A cone base coupled to the bottom of the cargo tank;
A first divided low mast unit coupled to the cone base;
A second divided low mast unit coupled to the first divided low mast unit; And
A plurality of upper mast units which are pre-coupled to the second divided low mast unit before the first divided low mast unit and the second divided low mast unit are coupled to each other,
The second divided low mast unit,
A second divided low mast body coupled to the first divided low mast unit; And
A pump tower coupled to the second divided low mast body and a plurality of upper mast mounting portion is fixed to the plurality of upper mast unit. The method of claim 1,
And the upper mast unit and the second divided low mast unit are bolted to each other. delete The method of claim 1,
The upper mast unit,
Upper mast body; And
One side is coupled to the upper mast mounting portion and the other side is coupled to the upper mast body including a pad module for allowing a relative vertical flow between the upper mast body and the upper mast mounting portion by a predetermined distance. 5. The method of claim 4,
The pad module,
A pad support plate coupled to the upper mast body and provided with a pad installation groove on a surface of the upper mast mounting portion opposite to the upper mast mounting portion; And
Pump tower comprising a pad installed in the pad installation groove. The method of claim 5,
The upper mast unit,
A pump tower further comprises a stopper coupled to the upper mast body to prevent the pad module from being pushed. The method according to claim 6,
And the pad support plate and the upper mast body are bolted to each other. The method of claim 7, wherein
The pad support plate,
Plate-like support plate body; And
It includes a pair of wings protruding from the support plate body,
The stopper is welded to the upper stopper body to support the pump tower, characterized in that the support. A main body for loading and unloading the liquefied natural gas into a cargo tank storing the liquefied natural gas (LNG);
A cone base coupled to the bottom of the cargo tank;
A first divided low mast unit coupled to the cone base;
A second divided low mast unit coupled to the first divided low mast unit;
A plurality of upper mast units pre-coupled to the second divided low mast unit before the first divided low mast unit and the second divided low mast unit are coupled to each other; And
And a pump seat unit coupled to the second divided low mast unit before the second divided low mast unit is coupled to the first divided low mast unit. 10. The method of claim 9,
And a stripping pump mounted to the pump seat unit to unload the liquefied natural gas inside the cargo tank.

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