KR20200032544A - Safety flare tower - Google Patents

Abstract

Disclosed is a safety flare tower. The safety flare tower can include: a tower body installed at a gas outlet unit; a flare tip which is installed in the top of the tower body and combusts gas; and a gas pipe installed between the gas outlet and the flare tip. Here, the gas pipe can include: a main gas pipe installed between the gas outlet and the flare tip; a compression pipe compressing the gas moved through the main gas pipe; and a swirl pipe which gives rotational force to the gas passed through a compression unit.

Description

Safety flare tower {SAFETY FLARE TOWER}

The present invention relates to a safety flare tower capable of maintaining the straightness of the flame.

In general, a flare system refers to any facility including a tower body that collects combustible materials and incinerates them to release into the atmosphere.

In such a flare tower, the temperature of the flare tower increases to 500 degrees Celsius or more, and structural stability of the tower structure may be deteriorated. Therefore, there is a problem in that the temperature standard of the coating material (paint, 塗料) for protecting the structure of the tower body is raised and the cost is increased.

In addition, the flare tower structure consists of a pipe diameter and a thickness that decreases from the bottom to the top, and in the case of medium and large-sized FPSO, its height exceeds 100 m.

When the height of such a flare tower structure is lowered, the construction cost is drastically reduced, but there is room for a safety accident to occur when a worker approaches the structure where the temperature rises as it approaches the heat source.

Therefore, it is required to reduce the construction cost by lowering the height of the flare tower while preventing the occurrence of worker safety accidents.

One embodiment of the present invention, to maintain the straightness of the flame burning in the flare tower to lower the installed height of the tower body structure to improve durability and to provide a safety flare tower that reduces the risk of safety accidents.

An embodiment of the present invention may include a tower body installed at a location of a gas outlet, a flare tip installed above the tower body to burn gas, and a gas pipe installed between the gas outlet and the flare tip. .

The gas pipe may include a main gas pipe installed between the gas discharge portion and the flare tip, a compression pipe compressing the gas moved through the main gas pipe, and a swirl pipe providing rotational force to the gas passing through the compression portion.

The compression pipe may include a compression body connected to the main gas pipe and an installation space formed therein, and a guide pipe installed in a conical shape having an inverted trapezoidal cross section in the installation space spaced apart from the inner wall surface of the compression body.

The compression pipe is formed between the outer surface of the guide pipe and the inner wall surface of the compression body, and the first guide flow path narrowed in the flare tip direction and the second guide flow path formed inside the guide pipe and expanded in the flare tip direction. It can contain.

The swirl pipe is installed to form a swirl space between the swirl body installed between the compression pipe and the flare tip and the inner wall surface of the swirl body, one side communicating with the guide pipe, and the other side opening in the flare tip direction. It may include a communication pipe and a swirl guide that is installed in the swirl space and discharges gas supplied from the compression pipe in a swirl state.

The swirl guide may be installed in at least one screw shape along the circumference of the communication pipe in the swirl space.

According to an embodiment of the present invention, the swirl flow of the gas passing through the swirl pipe is generated around the flame generated by the combustion of the gas in the flare tip, so that the external air is not directly acting on the flame and the straightness of the flame It is possible to secure.

Therefore, the influence of the wind on the flame generated from the flare tip is minimized so that the flame does not spread to the side of the tower body, and the durability of the tower body structure is weakened by the heat of the flame or a worker safety accident due to the flame is prevented. It is possible to do.

1 is a main cutaway view schematically showing a safety flare tower according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along line II-II of FIG. 1.
3 is a perspective view of a main portion schematically showing a state in which a swirl pipe is positioned inside the gas pipe of FIG. 1.
4 is a cross-sectional view of FIG. 1 taken along line IV-IV.
5 is a side view schematically illustrating a state of a flame in a safety flare tower according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains can easily practice. However, the present invention can be implemented in many different forms and is not limited to the embodiments described herein. In the drawings, parts not related to the description are omitted in order to clearly describe the present invention, and the same reference numerals are attached to the same or similar elements throughout the specification.

1 is a main cutaway view schematically showing a safety flare tower according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view taken along line II-II of FIG. 1.

1 and 2, the safety flare tower 100 according to an embodiment of the present invention includes a tower body 10 installed in a gas discharge unit 11 and an upper portion of the tower body 10 It is installed in the flare tip 20 for burning the gas, and includes a gas pipe 30 installed between the gas discharge unit 11 and the flare tip 20.

The tower body 10 may be installed to incinerate waste gas, which is a combustible or toxic substance, generated during the operation of collecting oil buried in the ground or the seabed, to be replaced with a non-toxic or non-combustible substance and then released into the atmosphere.

Here, the tower body 10 is installed at a position of the gas discharge unit 11 by a plurality of pipe frames, and a portion of the flare tip 20 in which gas is discharged in this embodiment will be schematically described.

The tower body 10 may be installed in a vertical or inclined protruding state at the position of the gas outlet 11 through which the waste gas is discharged.

A flare tip 20 for combustion of gas may be installed on the tower body 10.

The flare tip 20 is installed on the top of the tower body 10 and refers to a portion in which ignited gas is burned by operation of a burner and an ignition device (not shown).

The flare tip 20 may be installed at an upper position of the tower body 10 as the combustion of gas continues to generate significant heat due to flame.

The gas pipe 30 for supplying gas to the flare tip 20 is installed in the tower body 10.

The gas pipe 30 may be installed such that one side is connected to the gas outlet 11 at the bottom of the tower body 10 and the other end extends along the tower body 10 to supply gas to the flare tip 20.

The gas pipe 30 is installed along the tower body 10 to stably supply the gas supplied from the gas discharge unit 11 to the flare tip 20, and is installed as one in the tower body 10 in this embodiment. It will be described by way of example. However, the gas pipe 30 is not necessarily limited to being installed as one in the tower body 10, and may be installed in plural according to the amount of gas discharged from the gas discharge unit 11.

The gas pipe 30 includes a main gas pipe 31 installed between the gas discharge part 11 and the flare tip 20, and a compression pipe 33 compressing the gas moved through the main gas pipe 31, It may include a swirl pipe (35) for applying a rotational force to the gas passing through the compression pipe (33).

The main gas pipe 31 is installed to connect between the gas discharge unit 11 and the flare tip 20, and the inside may be installed to move the gas in a hollow state.

The main gas pipe 31 may be installed in a state in which the compressed pipe 33 and the swirl pipe 35 are connected so that the gas discharged in the direction of the flare tip 20 is supplied while maintaining straightness. Hereinafter, using the compression pipe 33 and the swirl pipe 35, the gas is supplied in a state in which the straightness is maintained in the direction of the flare tip 20, and the action of maintaining the straight state of the flame ignited in the flare tip 20 is more specifically As described.

First, the compression pipe 33 may be installed in a state connected to the main gas pipe 31 in a position close to the location where the flare tip 20 is installed. In this way, the compression pipe 33 is installed in a state connected to the main gas pipe 31, gives a compressive force to some gas moving through the main gas pipe 31, and the remaining part of the gas is a sufficient flow rate to the swirl pipe 35 It is intended to be supplied to.

In more detail, the compression pipe 33 is connected to the main gas pipe 31 and is installed in the installation space in a state spaced apart from the compression body 33a having an installation space therein and the inner wall surface of the compression body 33a. It may include a guide tube (33b) that is installed in a conical shape having an inverted trapezoidal cross section.

The compression body 33a is fixed while being connected to the main gas pipe 31, and a guide pipe 33b may be installed therein.

The guide tube 33b may be installed at a predetermined distance from the inner wall surface of the installation space of the compression body 33a in the interior of the compression body 33a.

The guide pipe 33b may be installed such that gas moving through the main gas pipe 31 is supplied to a plurality of flow paths in the direction of the swirl pipe 35.

The guide tube 33b is installed in a conical shape having an inverted trapezoidal cross section in the installation space spaced apart from the inner wall surface of the compression body 33a, and the inside may be formed in a hollow state.

Therefore, a first guide flow path 33c and a second guide flow path 33d through which gas is moved according to the installation of the guide pipe 33b may be formed inside the compression pipe 33.

The first guide flow path 33c is formed between the outer surface of the guide pipe 33b and the inner wall surface of the compression body 33a, and compresses a part of the gas moving through the main gas pipe 31 to swirl pipe ( 35) can be guided inside.

In the first guide flow path 33c, the outer surface of the guide pipe 33b is formed in a conical reverse direction, and the flow path gradually increases in an upward direction between the guide pipe 33b and the inner surface of the compression body 33a. It can be formed to narrow.

Therefore, the gas discharged in the direction of the swirl pipe 35 through the first guide flow path 33c may be discharged in a compressed state at a constant pressure.

On the other hand, the second guide flow path 33d is formed in a state penetrated inside the compression pipe 33, and the gas g may be moved in the direction of the compression pipe 33.

The second guide flow path 33d may be formed to be gradually expanded to increase the supply amount of gas in the upward direction. Therefore, the gas can be supplied to the swirl pipe 35 while the supply amount is increased while passing through the second guide flow path 33d.

On the other hand, the upper side of the compression pipe 33 may be installed a swirl pipe 35 for supplying the gas passing through the compression pipe 33 in a swirl state toward the flare tip 20.

3 is a perspective view of a main portion schematically showing a state in which a swirl pipe is positioned inside the gas pipe of FIG. 1, and FIG. 4 is a cross-sectional view of FIG. 1 taken along line IV-IV.

3 and 4, the swirl pipe 35, the swirl body 35a is installed between the compression pipe 33 and the flare tip 20, and the inner wall surface of the swirl body 35a It is installed so that a swirl space is formed between and the one side communicates with the guide tube 33b, the other side communicates with the flare tip 20, and the communication tube 35b is opened and installed in the swirl space and supplied from the compression tube 33. It may include a swirl guide (35c) for discharging the gas in a swirl (swirl) state.

The swirl body 35a may be extended so that one side has a long length in the direction of the flare tip 20 in contact with the compression tube 33.

A communication pipe 35b may be installed inside the swirl body 35a.

The communication pipe 35b may be installed in communication with the compression pipe 33 in the swirl space formed inside the swirl body 35a. The communication pipe 35b is formed in a cylindrical shape inside the swirl body 35a, so that the gas moved through the compression pipe 33 can be smoothly moved in the direction of the flare tip 20.

A swirl guide 35c may be formed around the outer circumference of the communication pipe 35b.

The swirl guide 35c is formed between the outer circumference of the communication pipe 35b and the inner wall surface of the communication pipe 35b, and may be formed in a screw type along the circumference of the communication pipe 35b.

Four swirl guides 35c may be formed in a screw type around the outer circumference of the communication pipe 35b.

Each of the swirl guides 35c may be formed in a screw type along the longitudinal direction of the communication pipe 35b, with one side contacting the outer circumference of the communication pipe 35b and the other side contacting the inner wall surface of the swirl body 35a. have.

Accordingly, the swirl guide 35c may be formed along the communication pipe 35b while dividing the swirl space formed between the communication pipe 35b and the swirl body 35a into four partition spaces 37.

Here, the swirl space may communicate with the first guide flow path 33c. Accordingly, the gas supplied to the swirl space through the first guide flow path 33c can be supplied in the direction of the flare tip 20 in a state where a swirl is formed by the screw shape of the swirl guide 35c.

As described above, in the process of supplying the gas g from the swirl pipe 35 to the flare tip 20 through the communication pipe 35b, a part of the gas may be supplied in the form of swirl through the swirl guide 35c.

That is, the central portion discharged through the swirl pipe 35 is supplied in a state in which straightness is secured, and the outer portion may be supplied in a swirl flow form by the swirl guide 35c.

Accordingly, the gas is prevented from flowing into the flame portion of the gas by the swirl action by the swirl guide (35c) in the process of combustion by the flare tip (20). It is possible that the straightness of the flame burned in the flare tip 20 is enhanced.

As described above, the safety flare tower 100 of the present embodiment allows the swirl flow of gas passing through the swirl pipe 35 around the flame generated by the combustion of the gas at the flare tip 20, It is possible to secure the straightness of the flame by preventing external air from directly acting on the flame.

5 is a side view schematically illustrating a state of a flame in a safety flare tower according to an embodiment of the present invention.

As shown in FIG. 5, the flow rate of the gas is slowed by the swirl flow of the gas g, so that the velocity gradient of the gas ejected through the swirl pipe 35 can be relaxed to stabilize the state of the exhaust gas. It is possible to improve the straightness of the flame f.

As described above, the directness of the flame generated on the upper portion of the tower body 10 is improved, so that the flame does not spread to the side of the tower body by the wind, and the durability of the tower body structure is weakened by the heat of the flame or due to the flame. It is possible to prevent the occurrence of worker safety accidents.

Although preferred embodiments of the present invention have been described through the above, the present invention is not limited thereto, and it is possible to carry out various modifications within the scope of the appended drawings and the detailed description of the claims and the invention. It is natural to fall within the scope of.

10 ... Tower body 11 ... Gas outlet
20 ... flare tip 30 ... gas pipe
31 ... Main gas pipe 33 ... Compression pipe
33a..Compression body 33b..Guide tube
33c..First Guide Euro 33d..Second Guide Euro
35 ... Swirl tube 35a..Swirl body
35b..Communication Officer 35c..Swirl Guide
37 ... Sectional space

Claims (5)

A tower body installed at a gas outlet position;
A flare tip installed on the tower body to burn gas; And
A gas pipe installed between the gas discharge part and the flare tip;
Including,
The gas pipe,
A main gas pipe installed between the gas discharge part and the flare tip; And
A compression pipe for compressing the gas moved through the main gas pipe; And
A safety flare tower including a swirl pipe that imparts rotational force to the gas passing through the compression part. According to claim 1,
The compression tube,
A compression body connected to the main gas pipe and having an installation space therein; And
A guide tube installed in a conical shape having an inverted trapezoidal cross section in the installation space while being spaced from the inner wall surface of the compression body
Safety flare tower, including. According to claim 2,
The compression tube,
A first guide channel formed between the outer surface of the guide tube and the inner wall surface of the compression body and narrowing in the flare tip direction; And
A second guide channel formed inside the guide tube and expanding in the flare tip direction
Safety flare tower, which further comprises. According to claim 3,
The swirl pipe,
A swirl body installed between the compression tube and the flare tip;
A swirl pipe formed to form a swirl space between the inner wall surfaces of the swirl body, one side communicating with the guide pipe and the other side communicating with the flare tip; And
A swirl guide that is installed in the swirl space and discharges the gas supplied from the compression pipe in a swirl state
Safety flare tower, including. According to claim 4,
The swirl guide, the safety flare tower is installed at least one screw-shaped along the periphery of the communication pipe in the swirl space.

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