KR101261855B1 - Apparatus for stabilizing flare - Google Patents

Abstract

Flare stabilization apparatus is disclosed. Flare stabilization apparatus according to an embodiment of the present invention, the flare system for incineration the waste gas transported through the waste gas transfer pipe, at least two conductive waste gas discharge nozzles spaced apart from each other to discharge the waste gas; And an electromagnetic field generating device connected to the waste gas discharge nozzles to supply a current, and generating an electromagnetic field between the waste gas discharge nozzles.

Description

Flare Stabilizer {Apparatus for stabilizing flare}

The present invention relates to a flare stabilization device.

In a plant system that produces petroleum or natural gas, the waste gas remaining after petroleum or natural gas refining is sent to the flare system, where all are incinerated.

The main component of the waste gas is a large amount of radiant heat emitted by incineration of hydrocarbon-based materials of various chemical species, which can damage the structure when the flame is directed to the surrounding structure of the plant system by the surrounding air flow. And adversely affect worker safety. In addition, if the waste gas blowing rate is too fast or strong wind blowing, there is a problem that the flame is lost to re-ignite.

Therefore, it is most important to ensure the stability of the flame when burning waste gas.

In the embodiment of the present invention, by forming an electromagnetic field near the waste gas discharge nozzle from which the waste gas is discharged, the flame is attached to the waste gas discharge nozzle to stabilize it.

In addition, the insulator is coupled to the waste gas discharge nozzle so that a current flows between the waste gas discharge point and the insulator, thereby improving the generation efficiency of the electromagnetic field by the current applied from the electromagnetic field generating apparatus.

In addition, the oscilloscope is used to check the strength and frequency of the electromagnetic field in real time, and sense the temperature near the waste gas nozzle by a temperature sensor and adjust the strength of the electromagnetic field according to the sensed temperature.

According to an aspect of the present invention, a flare system for incineration of waste gas transferred through a waste gas transfer pipe, comprising: at least two conductive waste gas discharge nozzles spaced apart from each other to discharge the waste gas; And an electromagnetic field generating device connected to each of the waste gas ejection nozzles to supply a current and generating an electromagnetic field between the waste gas ejection nozzles.

In addition, an insulator is coupled to the waste gas discharge nozzle at a predetermined distance from the waste gas discharge point at which the waste gas is discharged, and a current may flow between the waste gas discharge point and the insulator.

In addition, an oscilloscope for detecting the intensity and frequency of the electromagnetic field generated from the electromagnetic field generating device may be provided.

In addition, a temperature sensor may be disposed in close proximity to the waste gas discharge nozzle.

The apparatus may further include a controller configured to adjust the intensity of the electromagnetic field by comparing the temperature detected by the temperature sensor with an appropriate temperature during incineration.

The electromagnetic field generating device may supply a current to the waste gas discharge nozzle when the waste gas passes through the waste gas transfer pipe.

In the embodiment of the present invention, by forming an electromagnetic field near the waste gas discharge nozzle from which the waste gas is discharged, the flame can be stabilized by being attached to the waste gas discharge nozzle.

In addition, the insulator is coupled to the waste gas discharge nozzle so that a current flows between the waste gas discharge point and the insulator, thereby improving the generation efficiency of the electromagnetic field by the current applied from the electromagnetic field generator.

In addition, the oscilloscope may be used to check the strength and frequency of the electromagnetic field in real time, and sense the temperature near the waste gas nozzle by a temperature sensor and adjust the strength of the electromagnetic field according to the sensed temperature.

1 is a schematic conceptual diagram of a plant system.
2 is a schematic cross-sectional view of the flare stabilization apparatus according to the embodiment of the present invention.
3 is a block diagram of a flare stabilization apparatus according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described. The present invention is not limited to this embodiment.

First, a schematic configuration of a plant system will be described with reference to FIG.

As shown in FIG. 1, the plant system includes a waste gas transfer pipe 1, a knock-out drum 3, a liquid seal 4, a flare stack 5, and a gas barrier. Gas Barrier; 6), Pilot Burner; 7, Steam Nozzles; 8, Burner Ignition device;

The waste gas transfer pipe 1 is a path through which waste gas is transferred. In FIG. 1, a waste collection pipe (Gas Collection Header) 2 is installed in the waste gas transfer pipe 1 to check pressure, temperature, and the like of waste gas.

The knockout drum 3 is provided to remove water, oil, and the like contained in the waste gas by gravity precipitation. Water, oil, and the like are discharged to the lower side of the knockout drum 3.

The liquid chamber 4 precipitates impurities contained in the waste gas transferred from the knockout drum 3 and removes impurities using a purge gas. The liquid chamber 4 includes a waste gas injection pipe 4a into which waste gas is injected through the knockout drum 3, and a purge gas injection pipe 4b into which the purge gas is injected.

The waste gas is moved to the upper end of the flare stack 5 via the flare stack 5 and discharged from the waste gas discharge nozzle 10 (see FIG. 2) to be incinerated. At this time, the pilot burner 7 is operated by the burner ignition apparatus 9, and incineration is started.

The gas barrier 6 prevents the flame from rolling into the flare stack 5 side during incineration. In the gas barrier 6, a plurality of partitions 6a are provided so that the waste gas moves while moving in the vertical direction.

In addition, during incineration of the waste gas, the steam nozzle 8 injects steam to the flame side to cool radiant heat.

The flare stabilization apparatus according to the present embodiment is for stabilizing a flame formed when the waste gas is incinerated at the upper end of the flare stack 5. The flare stabilization apparatus according to the present embodiment is installed in the portion A of FIG. 1, and FIG. 2 schematically shows an enlarged portion A of FIG.

2 and 3, the flare stabilization device according to the present embodiment includes a waste gas discharge nozzle 10 and an electromagnetic field generating device 20.

The waste gas discharge nozzles 10 discharge waste gas, and are spaced apart from each other and at least two are disposed. The waste gas discharge nozzle 10 is made of a conductive material. For example, the waste gas discharge nozzle 10 may be steel.

Of course, the material of the waste gas discharge nozzle 10 is not limited to steel. As shown in FIG. 2, in this embodiment, two waste gas discharge nozzles 10 are provided inside the upper end of the flare stack 5.

The electromagnetic field generating device 20 is provided to generate an electromagnetic field in the vicinity of the waste gas discharge nozzle 10. The electromagnetic field generating device 20 is connected to each of the waste gas discharge nozzles 10 to supply a current. In the present embodiment, the electromagnetic field generating device 20 supplies a current to the waste gas discharge nozzle 10 when the waste gas passes through the waste gas transfer pipe 1.

As shown in FIG. 2, when an electromagnetic field is generated by the electromagnetic field generator 20, a flame may be stably attached near the waste gas discharge nozzle 10.

Specifically, when the flame is formed, ions such as OH ⁻ are generated, and the electromagnetic field provides the effect of pulling the ions so that the flame is stably positioned near the waste gas ejection nozzle 10 and incinerated.

Therefore, the flame is prevented from falling off from the waste gas discharge nozzle 10 due to the surrounding strong airflow, or the flame is lost.

In addition, the flare stabilization apparatus according to the embodiment of the present invention may further include an insulator 30, an oscilloscope 40, a temperature sensor 50, and a controller 60.

The insulator 30 is coupled to the waste gas discharge nozzle 10 at a predetermined distance from the waste gas discharge point at which the waste gas is discharged. Therefore, a current applied from the electromagnetic field generator 20 to the waste gas discharge nozzle 10 flows between the waste gas discharge point and the insulator 30.

In this embodiment, the insulator 30 is spaced downward from the waste gas discharge point, and no current flows downward from the point where the insulator 30 is disposed. Therefore, the current applied from the electromagnetic field generating device 20 is used to form the electromagnetic field without leakage, thereby improving the electromagnetic field generating efficiency.

The oscilloscope 40 detects the strength and frequency of the electromagnetic field generated from the electromagnetic field generator 20. Therefore, the operator can check the strength and frequency of the electromagnetic field generated by the electromagnetic field generating device 20 in real time.

The temperature sensor 50 is disposed close to the waste gas discharge nozzle 10 to sense a temperature in the vicinity thereof, and the control unit 60 detects the temperature detected by the temperature sensor 50 and incineration. In order to control the strength of the electromagnetic field by comparing the temperature.

For example, when the temperature caused by the flame is lower than the proper temperature when the waste gas is incinerated, the controller 60 controls the electromagnetic field generating device 20 to increase the intensity of the electromagnetic field so that the flame is more stably near the waste gas discharge nozzle 10. On the contrary, when the waste gas is incinerated, the electromagnetic field generating device 20 is controlled to lower the intensity of the electromagnetic field when the temperature of the flame is too high.

Hereinafter, the operation of the flare stabilization device of the present embodiment by the above configuration will be described in detail.

First, the electromagnetic field generating device 20 applies a current to the waste gas discharge nozzle 10 when the waste gas passes through the waste gas transfer pipe 1. Since the waste gas passing through the waste gas transfer pipe 1 moves quickly to the upper end of the flare stack 5, when the waste gas passes through the waste gas transfer pipe 1, current is applied to the waste gas discharge nozzle 10 to form an electromagnetic field. Thus, the stability of the flame is ensured from the start point of the waste gas incineration.

When the waste gas is incinerated, the oscilloscope 40 checks the strength and frequency of the electromagnetic field formed by the electromagnetic field generating device 20, and an operator can check the real-time state of the flare stabilization device using the same.

In addition, when the waste gas is incinerated, the temperature sensor 50 senses a temperature near the waste gas discharge nozzle 10. The control unit 60 adjusts the intensity of the electromagnetic field generated by the electromagnetic field generating device 20 by comparing the sensed temperature and the appropriate temperature during incineration.

At this time, the control unit 60 receives the strength and frequency information of the electromagnetic field from the oscilloscope 40, and continuously compares the temperature sensed by the temperature sensor 50 with the temperature of the flame changed by the change of the electromagnetic field. When the flame temperature reaches the proper temperature during incineration, the electromagnetic field is kept constant. As described above, the control unit 60 increases the strength of the electromagnetic field when the temperature of the flame is lower than the appropriate temperature, and conversely decreases the strength of the electromagnetic field when the temperature of the flame is higher than the proper temperature. To control.

Thus, the flare stabilization apparatus according to the present embodiment, by applying a current to the waste gas discharge nozzle 10 generates an electromagnetic field and the flame is stably maintained by the electromagnetic field, it is possible to incinerate the waste gas stably without the influence of the surrounding air flow have.

In addition, since the flame is aligned vertically with respect to the waste gas discharge nozzle 10 by the electromagnetic field, it is possible to prevent the surrounding structure constituting the plant system from being damaged by the flame.

In addition, the flare stabilization system according to the present embodiment contributes to the stable operation of the plant system because the temperature of the flame is kept constant during incineration.

As mentioned above, although preferred embodiment of this invention was described in detail, this invention is not limited to the said embodiment, A various many deformation | transformation may be provided within the range which does not deviate from the scope of the present invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10 ... waste gas nozzle 20 ... electromagnetic field generator
30 ... insulator 40 ... oscilloscope
50 ... Temperature sensor 60 ... Control unit

Claims (6)

In the flare system for incineration of waste gas transferred through the waste gas transfer pipe,
At least two conductive waste gas discharge nozzles spaced apart from each other to discharge the waste gas; And
And an electromagnetic field generating device connected to each of the waste gas ejection nozzles to supply a current, and generating an electromagnetic field between the waste gas ejection nozzles.
And the electromagnetic field generating device supplies a current to the waste gas discharge nozzle when the waste gas passes through the waste gas transfer pipe. The method of claim 1,
The waste gas discharge nozzle is flared stabilization apparatus, characterized in that the insulator is coupled a predetermined distance from the waste gas discharge point from which the waste gas is discharged, the current flows between the waste gas discharge point and the insulator. The method according to claim 1 or 2,
Flare stabilization apparatus characterized in that the oscilloscope for detecting the intensity and frequency of the electromagnetic field generated from the electromagnetic field generating device. The method of claim 3,
Flare stabilization apparatus characterized in that the temperature sensor is disposed in close proximity to the waste gas discharge nozzle. 5. The method of claim 4,
Flare stabilization apparatus further comprises a control unit for adjusting the intensity of the electromagnetic field by comparing the temperature detected by the temperature sensor with the appropriate temperature during incineration. delete

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