KR20180122793A - Vent mast - Google Patents

Abstract

Disclosed is a structure of a vent mast. The vent mast according to the present invention comprises: a discharge pipe through which gas discharged from a storage tank is transferred; a head installed at an upper portion of the discharge pipe; a drip pan installed inside the head; a drain box installed at the bottom of the drip pan inside the head; and a blocking plate provided under the head. Therefore, it is possible to suppress a down flow phenomenon in which some gas is jetted down from the head to the vent mast.

Description

Vent mast

The present invention relates to a vent mast which prevents a down flow phenomenon in which a part of gas is jetted down from a head of a vent mast.

Natural gas is transported in the form of gas via land and sea gas pipelines, or stored in LNG transports in the form of liquefied natural gas (LPG) or liquefied petroleum gas (LPG) and transported to remote sources.

LNG carriers (LNG carriers) and LNG RVs (Regasification vessels) are available for transporting LNG.

In addition, LNG FPSO (Floating, Production, Storage and Offloading), LNG FSRU (Floating Storage and Regasification Unit) and F (Floating) -LNG plants are offshore plants to store LNG.

In this way, a storage tank for storing LNG in a cryogenic condition is installed in a marine structure for storing LNG transporting line or LNG, which transports liquid cargo such as LNG, and a vent mast corresponding to each storage tank ), And if necessary, releases various gases generated in the storage tank through the vent mast to the atmosphere.

1 (a) is a side view, (b) is a cross-sectional view, and FIG. 1 (c) is a perspective view.

1 (a) to 1 (c), the vent mast 1 includes a discharge pipe 10 and a head 20 installed on an upper portion of the discharge pipe. Various gases generated in the storage tank are sent to the head 20 via the discharge pipe 10 and discharged to the atmosphere through the discharge port 21 formed in the upper portion of the head 20. [

A drip pan 30 is installed inside the head 20 to prevent rainwater or the like from flowing into the discharge pipe 10.

The drip pan 30 has a diameter larger than that of the discharge port 21 in order to block the inflow of rainwater or the like into the discharge pipe 10 and prevents the discharge of the gas to the discharge port 21, It should have a smaller diameter than the inner diameter.

The gas transferred from the discharge pipe 10 to the inside of the head 20 is discharged to the discharge port 21 through the space between the drip pan 30 and the inner wall of the head 20.

The drip pan 30 may have a funnel shape so that the rainwater flowing into the drip pan 30 can be gathered at the central portion. The rainwater collected at the center of the drip pan 30 is discharged to the outside of the vent mast 1 A drain pipe 31 may be installed.

The lower inner wall of the head 20 is spaced from the peripheral surface of the discharge pipe 10 due to the difference between the lower diameter of the head 20 and the diameter of the discharge pipe 10, A space 22 is formed between the discharge pipes 10 so that when the rainwater is excessively introduced into the drip pan 30 and the rainwater overflows from the drip pan 30, the overflowing rainwater does not flow into the discharge pipe 110 And the space (22) formed in the lower portion of the head (20).

Generally, a vent mast provided on a ship is manufactured by GTT, and has a structure as shown in Fig.

On the other hand, the vent mast structure has the following problems.

1, there is an empty space E between the discharge pipe 10 and the drip pan 30 inside the head 20, and the gas transferred through the discharge pipe 10 flows into the empty space E and discharged into the discharge port 21 through a space separated between the inner wall of the head 20 and the drip pan 30. [

However, in the empty space E, as shown by an arrow A, a recirculation region in which a part of the gas descends toward the discharge pipe 10 is likely to occur, and a part of the gas circulating along the recirculation region is discharged from the head 20 A down flow phenomenon occurs, which is ejected to the deck side through the spacing space 22 formed in the lower part of the rear side.

The downflow phenomenon occurring in the vent mast shown in Fig. 1 is shown in Fig. It is very dangerous that a flammable gas is jetted down toward the deck side, which can lead to serious safety problems.

SUMMARY OF THE INVENTION In order to solve the above problems, the present invention has been made to solve the above-mentioned problems by changing the structure of the vent masthead to suppress the occurrence of a downflow phenomenon in which some gases are jetted down from the vent masthead, do.

In order to achieve the above-mentioned object, the present invention is characterized in that a drain box is installed at a lower portion of a drip pan installed in a head of a vent mast so that the drain box occupies a space inside the head Thereby preventing the recirculation of gas from occurring within the head and preventing the recirculation of the gas through the outlet of the vent hole at a position spaced downwardly away from the spaced apart space existing between the lower inner wall of the head and the outlet tube of the vent mast, And the flow of the gas discharged downward of the head is switched in the horizontal direction.

The drain box is formed to have a funnel shape at its bottom, so that the gas inside the head forms a smooth flow to an outlet formed in the upper portion of the head.

Further, the vent mast according to the present invention is characterized in that the vent mast includes: a head for collecting and discharging gas transferred from the discharge pipe; A drip pan installed inside the head to prevent rainwater from flowing into the discharge pipe; A drain box installed at a lower portion of the drip pan to occupy a space inside the head to prevent recirculation of gas; And a blocking plate provided under the head.

The drain box has a circumferential surface parallel to the inner wall surface of the head, and a lower portion has a funnel shape.

The drain box can be determined in diameter and depth so as to maintain a constant flow rate while the gas discharged through the vent mast flows from the discharge pipe to the outlet formed in the upper portion of the head.

The drip pan may be spaced apart from the inner wall of the head by a plurality of first attachment members installed along the inner wall of the head.

The vent mast according to the present invention may further include a drain pipe installed at a lower portion of the drip pan and discharging the rainwater introduced into the drip pan to the outside of the vent mast.

The drain pipe may be formed to penetrate the drain box and the head.

The drain box may be spaced apart from the inner wall of the head by a plurality of second mounting members provided along the inner wall of the head.

The drip pan may be mounted on the upper portion of the drain box, and the drip pan and the drain box may be integrally formed.

The first mounting member and the second mounting member may also be integrally formed.

The head may be spaced from the peripheral wall of the discharge pipe by a plurality of third installation members installed along the peripheral wall of the discharge pipe.

The blocking plate may be installed along the periphery of the discharge pipe so as to be spaced downward from a space formed between the inner bottom wall of the head and the discharge pipe.

The plurality of third mounting members may be installed to protrude below the head.

The barrier plate may be installed along the periphery of the discharge pipe while being in contact with the lower end surface of each of the third installation members.

The barrier plate may have a ring shape.

The present invention also provides an offshore structure including a vent mast having the above-described features.

The vent mast according to the present invention can reduce the risk of explosion by suppressing the down flow phenomenon in which a part of the gas is jetted down from the vent mast head by changing the structure of the vent mast head, Accordingly, the amount of explosion-proof equipment to be provided on the deck can be reduced, thereby reducing the production cost.

1 (a) is a side view, (b) is a cross-sectional view, and FIG. 1 (c) is a perspective view.
FIG. 2 is a view showing a down flow phenomenon of some gas generated in the vent mast.
3 is a view showing the structure of a vent mast according to the present invention, wherein (a) is a side view, (b) is a sectional view, and (c) is a perspective view.
Fig. 4 is a view showing the gas flow inside the vent mast. Fig. 4 (a) is a gas flow inside the vent mast shown in Fig. 1, and Fig. 4 (b) is a gas flow inside the vent mast according to the present invention.
FIG. 5 is a view showing the flow of gas ejected from the vent mast, in which (a) shows the flow of gas ejected from the vent mast shown in FIG. 1, (b) shows the flow of gas ejected from the vent mast according to the present invention Respectively.

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. Like reference symbols in the drawings denote like elements.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. 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.

3 is a view showing the structure of a vent mast according to the present invention, wherein (a) is a side view, (b) is a sectional view, and (c) is a perspective view.

3 (a) to 3 (c), the vent mast 100 according to the present invention includes a discharge pipe 110 through which gas discharged from a storage tank is transferred; A head 120 installed at an upper portion of the discharge pipe 110; A drip pan 130 installed inside the head 120; A drain box 140 installed at a lower portion of the drip pan 130; And a blocking plate 150 installed below the head 120.

A discharge port 121 for discharging the gas transferred from the storage tank through the discharge pipe 110 is formed in the upper portion of the head 120.

A drip pan 130 is installed inside the head 120 to prevent rainwater or the like from flowing into the discharge pipe 110.

1, the drip pan 130 has a larger diameter than the discharge port 121 formed in the upper portion of the head 120 to block rainwater or the like from entering the discharge pipe 110, Has a diameter smaller than the inner diameter of the head (120) so as not to completely block the path to the discharge port (121).

The drip pan 130 may be installed inside the head 120 by the first mounting member 101 so that the drip pan 130 is separated from the inner wall of the head 120 by the first mounting member 101. [ By being installed, a passage through which the gas is discharged through this spaced-apart space is provided.

The drip pan 130 may have a funnel shape so that rainwater or the like flowing into the drip pan 130 can be gathered at a central portion. The rainwater flowing into the lower portion of the drip pan 130 is discharged to the outside of the vent mast 100 A drain pipe 131 may be provided. The drain pipe 131 may be provided to penetrate the drain box 140 and the head 120.

The drain box 140 is installed below the drip pan 130. The drain box 140 is connected to the inner wall of the head 120 by the second mounting member 102 so as to have a space spaced between the drain box 140 and the inner wall of the head 120, It can be installed so as to be spaced apart.

The drain box 140 may be welded in a state where the drip pan 130 is seated on the upper part and may be installed inside the head 120 after the drip pan 130 and the drain box 140 are integrally manufactured . The first mounting member 101 for fixing the drip pan 130 to the inside of the head 120 and the second mounting member 102 for fixing the drain box 140 to the inside of the head 120 are also integrally formed .

The lower end of the drain box 140 has a funnel shape like the drip pan 130 so that the gas transferred from the discharge pipe 110 to the inside of the head 120 reaches the discharge port 121 at the upper part of the head 120 Flow can be formed.

The drain box 140 may be provided so that its circumferential surface is parallel to the inner wall surface of the head 120 and a part of the lower end portion may be provided to penetrate the inner space of the discharge tube 110.

The drain box 140 is configured such that the diameter, the depth, and the like are determined so that the gas discharged through the vent mast 100 can flow while maintaining the maximum constant flow rate while flowing along the arrows shown in FIG. 3 (b) .

The drain box 140 occupies most of the space between the drip pan 130 and the discharge tube 110 inside the head 120. [ Therefore, since there is almost no empty space inside the head 120 except for the passage space for allowing the gas to reach the discharge port 121 above the head 120, a gas recirculation region is generated inside the head 120 Therefore, the down flow phenomenon of the gas does not occur.

The head 120 has a diameter smaller than the diameter of the discharge tube 110 and the head 120 is connected to the third installation member 103 (Not shown).

Accordingly, a space 122 is formed in the lower portion of the head 120, which is a space between the inner wall of the head 120 and the discharge pipe 110.

The blocking plate 150 is installed along the periphery of the discharge pipe 110 at a position spaced downward from the spacing space 122 formed below the head 120 by a certain distance.

The plurality of third mounting members 103 may protrude from the lower portion of the head 120 and the blocking plate 150 may contact the lower end surfaces of the third mounting members 103, Can be installed. The blocking plate 150 may be provided in a ring shape along the periphery of the discharge pipe 110.

The blocking plate 150 has a role of generating a downward current in the head 120 and changing the flow of a part of the gas blown downward through the space 122 in the lower end of the head 120 into a flow in the horizontal direction do.

3, the operation of discharging the gas through the vent mast 100 according to the present invention will be described.

The gas to be discharged is conveyed along the discharge pipe 110 of the vent mast 100 and discharged through the discharge port 110 at the upper end of the head 120 through the head 120 121 to the atmosphere.

The gas transferred from the discharge pipe 110 to the inside of the head 120 flows through the gap between the drip pan 130 and the drain box 140 and the inner wall of the head 120 as indicated by arrows in FIG. And is discharged to the discharge port 121 through the space.

There is almost no empty space inside the head 120 except for the space between the drip pan 130 and the drain box 140 and the inner wall of the head 120, that is, the passage for the gas to move to the discharge port 121, There is almost no possibility that a gas recirculation region occurs inside the head 120 as shown in Fig.

Also, if the amount of gas discharged through the discharge pipe 110 is excessive, a gas recirculation region is generated inside the head 120 to cause a downflow in which some gases are lowered, So that no flow of gas descending toward the deck side is generated.

Fig. 4 is a view showing the gas flow inside the vent mast. Fig. 4 (a) is a gas flow inside the vent mast shown in Fig. 1 and Fig. 4 (b) is a gas flow inside the vent mast according to the present invention.

Referring to Fig. 4, the gas flow inside the vent mast according to the present invention and the vent mast shown in Fig. 1 are compared.

Referring to FIG. 4A, in the vent mast shown in FIG. 1, the gas that has risen through the exhaust pipe is discharged to the atmosphere through the discharge port at the top of the head, a gas recirculation region is generated in the empty space inside the head, A flow (a flow indicated by an arrow) occurs in which the gas is ejected downward through the spacing space under the head.

In the vent mast shown in Fig. 1, since there is a lot of empty space inside the head and the gas moves from the empty space to the narrow space between the drip pan and the inner wall of the head, suddenly the flow area is reduced, A recirculation zone is likely to occur.

4 (b), most of the space inside the vent mast head according to the present invention is occupied by the drip pan and the drain box. Therefore, except for a space for discharging the gas along the inner wall of the head, Is almost nonexistent.

Thus, the gas transferred through the discharge tube is discharged from the upper portion of the discharge tube (or the lower portion of the head) along the narrow space at a high speed to the discharge port at the top of the head, and no gas recirculation area is generated inside the head.

Nevertheless, due to factors such as the pressure inside the head, some of the gas can be discharged downward through the spacing space below the head. The amount of this gas is very small, as can be seen from FIG. 4 (b) It can be seen that a part of the gas discharged through the space is not discharged toward the direct lower chamber toward the deck but the flow is switched and discharged in the horizontal direction by the blocking plate.

FIG. 5 is a view showing the flow of gas ejected from the vent mast, in which (a) shows the flow of gas ejected from the vent mast shown in FIG. 1, (b) shows the flow of gas ejected from the vent mast according to the present invention Respectively.

Referring to FIG. 5 (a), it can be seen that in the vent mast shown in FIG. 1, an amount of gas similar to the gas discharged to the upper portion of the head is discharged toward the deck side from the lower portion of the head.

5 (b), in the vent mast according to the present invention, the gas discharged from the lower portion of the head is remarkably reduced as compared with the vent mast shown in FIG. 1. In the vent mast according to the present invention, The gas does not affect the deck because the exhaust stream is formed horizontally rather than directly below the deck.

The results of the gas flow discharged from the vent mast shown in FIG. 1 and the gas flow discharged from the vent mast according to the present invention are shown in Table 1 below.

Mass Flow Rate [kg / s]

Distribution Rate [%]

Inlet

Down Flow

Up Flow

Down Flow

Up Flow

1

53.01

21.31

31.70

40.20

59.80

Invention

53.01

5.59

47.42

10.55

89.45

4, 5 and Table 1, in the vent mast shown in FIG. 1, gas of about 40.2% of the total gas was ejected downward of the vent masthead, whereas in the vent mast of the present invention, % Of the gas is ejected horizontally through the spacing space at the bottom of the vent masthead.

While the present invention has been particularly shown and described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And should not be construed as limiting the scope of the invention.

100: Vent mast
110:
120: Head
121: Outlet
122: Spacing space
130: Drip pan
131: Water pipe
140: Drain box
150: Blocking plate

Claims (13)

In the vent mast,
A drain box is installed in a lower portion of a drip pan installed inside the head of the vent mast so that the drain box occupies a space inside the head so that a gas recirculation region is generated inside the head Therefore,
A blocking plate is provided along the periphery of the discharge pipe at a position spaced downward from a spaced space existing between the lower inner wall of the head and the discharge tube of the vent mast so that the flow of the gas discharged downwardly of the head is horizontally Lt; / RTI >
Bent mast. The method according to claim 1,
Wherein the drain box is formed with a funnel shape at its bottom so that gas inside the head forms a smooth flow to an outlet formed in the top of the head,
Vent mast construction. A head for collecting and discharging the gas transferred from the discharge pipe;
A drip pan installed inside the head to prevent rainwater from flowing into the discharge pipe;
A drain box installed at a lower portion of the drip pan to occupy a space inside the head to prevent recirculation of gas; And
And a blocking plate provided under the head.
Bent mast. The method of claim 3,
Wherein the drain box has a circumferential surface parallel to an inner wall surface of the head, and a lower portion has a funnel shape,
Bent mast. The method of claim 4,
Wherein the diameter and depth of the drain box are determined such that the gas discharged through the vent mast is maintained at a constant flow rate while flowing from the discharge pipe to the discharge port formed in the upper portion of the head.
Bent mast.
The method of claim 3,
The drip pan
And a plurality of first mounting members provided along an inner wall of the head, the first mounting members being spaced apart from an inner wall of the head,
Bent mast. The method of claim 6,
And a drain pipe installed at a lower portion of the drip pan and discharging the rainwater flowing into the drip pan to the outside of the vent mast,
Wherein the drain pipe is formed to penetrate the drain box and the head,
Bent mast. The method of claim 6,
The drain box
And a plurality of second mounting members installed along the inner wall of the head,
Bent mast. The method of claim 8,
Wherein the drip pan is seated on an upper portion of the drain box, the drip pan and the drain box are integrally formed,
Wherein the first mounting member and the second mounting member are integrally formed,
Bent mast. The method of claim 3,
The head is spaced from the peripheral wall of the discharge pipe by a plurality of third installation members installed along the peripheral wall of the discharge pipe,
Wherein the barrier plate is spaced downwardly from a space formed between the inner bottom wall of the head and the discharge pipe and is installed along the periphery of the discharge pipe,
Bent mast. The method of claim 10,
The plurality of third mounting members are provided so as to protrude from the lower portion of the head,
Wherein the barrier plate is disposed along the periphery of the discharge pipe in contact with the lower end surface of each of the third installation members,
Bent mast. The method of claim 10,
Wherein the barrier plate has a ring shape,
Bent mast. An offshore structure having a vent mast of any one of claims 1 to 12.

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