KR20120043305A - Pump tower for liquified gas carrier - Google Patents

Abstract

PURPOSE: A pump tower for a liquefied gas carrying vessel is provided to reduce the flow load of liquefied gas applied to the pump tower by simplifying a reinforcing structure for the center part of the pump tower. CONSTITUTION: A pump tower for a liquefied gas carrying vessel comprises multiple main pipes(1) and multiple reinforcing members. The main pipes charge liquefied gas into baggage racks or discharge the liquefied gas to the outside. The reinforcing members connect the main pipes to a support. Multiple unit horizontal reinforcing members(2) are installed in the center part of the pump tower at certain vertical intervals. The horizontal reinforcing members are installed in the upper part and the lower part where stress is mainly applied except for the center part. The two unit horizontal members neighboring each other are connected by a diagonal reinforcing member(3).

Description

Pump Tower for Liquefied Gas Carrier {Pump tower for Liquified Gas carrier}

The present invention relates to a pump tower for a liquefied gas carrier having a wide support structure arrangement. Specifically, the present invention relates to a pump tower having sufficient load bearing capacity while eliminating unnecessary structures of a member supporting the main pipe of the pump tower. A pump with a structure that can increase productivity and safety by satisfying the necessary strength for stable support of the pump tower while arranging the vertically spaced intervals between the unit horizontal stiffeners connecting the main pipes made horizontally at a wider interval than the conventional pump tower. It's about the tower.

Recently, due to global warming or environmental problems, instead of fossil fuels such as petroleum and coal, the use of natural gas, which is the fossil fuel that emits the least pollutants and generates only half of the carbon dioxide, has emerged. In recent years, production is rapidly increasing for transportation raw materials or electric power, and thus has been spotlighted as a new energy source.

However, such natural gas exists in a gaseous state, and the distance between the place of production and the place of consumption is remote, so it is not easy to transport in the offshore gas field that is not produced in the land gas field.

In other words, natural gas is methane-based natural gas, and a liquefied gas carrier that transports it is a colorless transparent cryogenic liquid that cools the state of natural gas to -163 ℃ and reduces its volume to 1/600. It is carried in the gas (LNG) state. Such LNG is transported by LNG carriers in mountainous regions, stored in onshore LNG terminals, and supplied to consumers.

Liquefied gas carriers are used as a means of safely transporting liquefied natural gas. In other words, a liquefied gas carrier that stores liquefied natural gas in a cryogenic state is a vessel for loading a liquefied gas into the sea to unload the liquefied gas to a land demand, and for this purpose, a special storage that can withstand the cryogenic temperature of the liquefied gas. It includes a tank, a cargo hold.

Types of cargo hold are typically membrane hold and independent hold. Membrane type is not to make a separate tank, but to form the surface structure for the insulation on the wall of the cargo hold, and then attach a special metal plate to the insulation surface, and the independent type is to make a separate cargo hold and to install it on the ship.

Among them, the pump tower is installed in the membrane-type cargo hold and used to store and discharge the liquefied natural gas. The pump tower depends on the size of the liquefied gas carrier, but the height of the liquefied gas carrier is about 30m. Branches are large structures.

Hereinafter, a conventional pump tower structure will be described.

3 is a front view illustrating a structure of a pump tower according to an exemplary embodiment, and FIG. 4 is a cross-sectional view taken along line A-A of the pump tower according to an exemplary embodiment.

As shown in the related art, a conventional general pump tower is provided with complex horizontal and diagonal reinforcements supporting triangularly located main pipes and main pipes so as to withstand the flow of liquefied gas due to the movement of a vessel during operation. The main pipe is mainly used as the discharge pipe, filling pipe, and one emergency pipe of liquefied natural gas, and the number may vary slightly depending on the nature.

As described above, the horizontal and diagonal stiffeners supporting the main pipes to withstand the flow of liquefied gas due to the movement of the vessel during operation, such as the distortion of horizontal stiffeners up and down the horizontal stiffeners supporting the main pipes in the horizontal direction It consists of diagonal stiffeners connected up and down to withstand the movement of the main pipe according to the flow of liquefied gas during operation.

However, in the structure of the conventional pump tower as described above, the horizontal reinforcement installed in order to increase the strength is densely installed in the vertical direction compared to the height of the entire pump tower, and by connecting the upper and lower horizontal reinforcement of the horizontal reinforcement with diagonal reinforcement, the ship in operation It has the advantage of increasing the structural strength of the pump tower to withstand the flow of liquefied gas due to the movement of the liquefied gas.However, in order to have this advantage, the liquefied gas with the increased load of the pump tower due to the use of excessive horizontal reinforcement and horizontal reinforcement The additional flow loads were added to the pump tower by being exposed to the flow of, resulting in a problem that hindered the stable operation of the liquefied gas carrier.

An object of the present invention for solving the above problems is to reduce the horizontal load and the diagonal reinforcement used in the pump tower of the liquefied gas carriers to reduce the area of the reinforcement exposed to the liquid flow while reducing the flow load added to the pump tower In order to provide a pump tower that is simplified and lightweight, the pump tower structure is simplified by reinforcing the upper and lower portions of the pump tower where high stress occurs due to the constraint of the pump tower.

The present invention to achieve the object as described above and to solve the conventional drawbacks consists of a plurality of main pipes to fill the liquefied gas into the cargo hold or discharged to the outside, and a plurality of reinforcing materials connected to the main pipes to support them. In the pump tower installed in the liquefied gas carrier,

A plurality of unit horizontal reinforcement is installed in the vertical direction with a predetermined interval in the central portion corresponding to the section of 30 to 60% based on the pump tower height 100%,

Except for the central section having the section height of 30 ~ 60%, the upper part and the lower part where the main stress is applied are configured to have 20 to 35% section based on 100% of the height of the pump tower, and are installed at regular intervals. The horizontal reinforcement is installed in the vertical direction, and is achieved by providing a pump tower for a liquefied gas carrier, characterized in that configured to support by connecting the diagonal reinforcement between the upper and lower neighboring unit horizontal reinforcement.

In one embodiment of the present invention, the unit horizontal reinforcement of the central portion may be installed in the unit horizontal reinforcement in the vertical direction at intervals of 10 to 30% based on 100% of the height of the pump tower.

In one embodiment, the upper end or the lower end may be installed in the horizontal reinforcement in the vertical direction at intervals of 10% or less based on the pump tower height 100%.

As described above, the present invention simplifies the central structure of the pump tower of the liquefied gas carrier to reduce the flow load of the liquefied gas added to the pump tower, and reinforces the upper and lower parts of the high stress to reduce the weight of the entire pump tower structure to increase productivity and safety. It is a useful invention having the advantage of realizing the improvement is an invention that is expected to be greatly used in the industry.

1 is a front view showing the structure of a pump tower according to an embodiment of the present invention,
2 is a cross-sectional view taken along line CC of the pump tower according to an embodiment of the present invention,
3 is an exemplary front view showing the structure of a pump tower according to a conventional embodiment;
4 is a cross-sectional view taken along the line AA of the conventional pump tower.

Hereinafter, the configuration and the operation of the embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

1 is a front view showing a structure of a pump tower according to an embodiment of the present invention, Figure 2 is a cross-sectional view taken along line C-C of the pump tower according to an embodiment of the present invention.

As shown, the basic configuration of the pump tower according to the present invention is composed of a main pipe (1) installed in a vertical direction consisting of a plurality of pump towers. In the configuration according to the illustrated embodiment, three main pipes 1 are configured. The main pipe 1 is mainly used as a discharge pipe, a filling pipe, and one emergency pipe of the liquefied natural gas, and the number may vary slightly depending on the nature.

Triangularly located main pipes according to one embodiment of the present invention is a horizontal unit of triangular shape consisting of three horizontal reinforcing material to connect each main pipe (1) in the horizontal direction to support the vibration of the main pipe (1) according to the flow of liquefied gas It is comprised so that it may be fixed by the reinforcement 2.

The unit horizontal reinforcing material (2) is provided in a quantity which is significantly smaller in number than the conventional pump tower.

That is, according to the present invention, the pump tower height (pump tower lower base to pump tower upper dome) is 100%, and the center portion 4 corresponding to 30 to 60% has a pump tower height of 10 to 30%. The unit horizontal stiffener (2) was installed at the vertical length interval corresponding to%.

In addition, the upper portion 5 and the lower portion 6, which are pump tower sections other than the central portion 4 corresponding to 30 to 60%, respectively, are installed at vertical length intervals of 10% or less based on 100% of the height of the pump tower. Horizontal reinforcement was installed in the vertical direction.

In addition, a plurality of unit horizontal stiffeners (2) installed in the central portion (4) section corresponding to 30 ~ 60% based on the pump tower height 100% in the main pipe alone without the diagonal stiffener (3) connected diagonally between the upper and lower (1) was configured to support. In this way, the load of the pump tower by the diagonal reinforcement 3 can be remarkably reduced, and the flow load of the liquefied gas added to the pump tower is reduced. The reason for limiting the central section (4) to 30 to 60% based on 100% of the height of the pump tower is less than this. This is because it is impossible to achieve the purpose, and if it is larger than this, the interval between the center portion 4 is increased so that the height of the upper portion 5 and the lower portion 6 where the stress is high cannot be secured. This is because the upper and lower intervals of 2) must be narrowed, and the diagonal reinforcement 3 must be used to achieve the object of the present invention.

In addition, the interval between the unit horizontal reinforcement to be installed in the central portion (4) is less than 10% the reason for installing the unit horizontal reinforcement (2) in the vertical length interval corresponding to each 10 ~ 30% of the height of the pump tower 100% This is because it is impossible to achieve the purpose of reducing the flow load applied to the pump tower by reducing the area of the reinforcement according to the decrease in the number of horizontal reinforcement (2). This is because the flow load of the gas can cause damage to the structure.

However, the pump tower sections other than the central section 4 corresponding to 40 to 70% except the central section 4 with 30 to 60% of stress, that is, the upper section 5 and the lower section 6 section 20 to 20 In the 35% section, the diagonal stiffener (3) supporting the vertical direction between the unit horizontal stiffeners (2) was installed to support the stress due to the liquid flow.

At this time, the vertical length between the unit horizontal reinforcing material (2) installed in each of the upper end portion 5 and the lower end portion 6 is a plurality of horizontal installed at vertical length intervals of 10% or less based on the pump tower height as described above The reason why the reinforcing material is installed is that when the length is greater than 10% of the vertical unit length, the length of the diagonal reinforcing material 3 is increased and the structural stability of the upper end part 5 and the lower end part 6 in which the stress is high is lowered. In addition, if the lower limit value is less than 10% and is too narrow, even if the response to stress is increased, but the load reduction effect due to the reduction in the number of horizontal reinforcement (2) of the central portion (4) can be used about 5%.

In addition, the length of the horizontal reinforcing material (2) connecting the main pipe may be used about 10% based on 100% of the height of the pump tower.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

<Explanation of symbols for the main parts of the drawings>
(1): Main piping (2): Unit horizontal stiffener
(3): diagonal stiffener (4): center part
(5): upper part (6): lower part

Claims (3)

In the pump tower installed in the liquefied gas carrier ship consisting of a plurality of main pipes to fill or discharge the liquefied gas into the cargo hold and a plurality of reinforcement to support the connection between the main pipes,
A plurality of unit horizontal reinforcement is installed in the vertical direction with a predetermined interval in the central portion corresponding to the section of 30 to 60% based on the pump tower height 100%,
Except for the central section having the section height of 30 ~ 60%, the upper part and the lower part where the main stress is applied are configured to have 20 to 35% section based on 100% of the height of the pump tower, and are installed at regular intervals. A liquefied gas carrier ship tower comprising horizontal reinforcing materials installed in the vertical direction and configured to be supported by connecting diagonal reinforcing materials between vertical horizontal neighboring units.
The method according to claim 1,
The unit horizontal reinforcement of the central portion is a pump tower for a liquefied gas carrier, characterized in that the unit horizontal reinforcement is installed in the vertical direction at intervals of 10 to 30% based on the pump tower height 100%.
The method according to claim 1,
The upper portion or the lower portion of the pump tower for the liquefied gas carrier ship, characterized in that the horizontal reinforcing material is installed in the vertical direction at intervals of 10% or less based on the height of the pump tower 100%.

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