KR102043674B1 - Oil mist seperator - Google Patents

Abstract

One embodiment of the present invention,
The impurities contained in the gas transferred from the gas supply pipe to the first separation device are first separated by the vortices formed inside the first separation device, and the impurities contained in the gas passing through the first separation device are secondary. A water / oil separator for separating: A second separator for separating impurities from a gas passing through the first separator, wherein the gas from which impurities are first separated through the first separator is introduced. housing; An insulator installed on one side of the housing and fixed to one side of an electrode support frame to which a high voltage is supplied from the outside; A discharge electrode accommodated in an inner center and supplied with a high voltage through the insulator support frame of the insulator, and rotatably installed in the housing, and collect impurities on the inner surface by discharge from the discharge electrode; In the rotation, the impurity is separated from the gas by centrifugal force, but the separated impurity is formed of a cone-shaped porous plate whose front end is blocked so that the impurity can be moved to the opening along the inclined plane and the filtered air can be discharged outward through the through hole. Impurity separator; A discharge pipe connected to the discharge port of the housing and discharging the filtered air passing through the second separator to the outside, wherein the operation of the first separator and the second separator is temporarily stopped. In this case, the oil-water separator further comprises a bypass pipe for directly transferring the gas transferred through the gas supply pipe to the outlet pipe outlet side of the second separator without transferring the gas to the first separator. do.

Description

Oil-water separator {OIL MIST SEPERATOR}

The present disclosure relates to an oil / water separator, and more particularly, to an oil-water separator for collecting, separating, and removing impurities such as oil mist or water contained in COG.

In general, COG refers to a coke oven gas (Coke Oven Gas, hereinafter referred to as 'COG') generated in the process of producing coke by the dry distillation process using coal containing moisture. Such COG is recovered as a by-product and transferred through the coke oven gas transfer pipe to be used as a heat source in a unit process of a steel mill.

Since COG contains impurities such as tar, hydrogen sulfide, and oil mist, its heat supply ability is poor, and thus it is not suitable for being used as a heat source.In particular, COG may cause corrosion or blockage on the pipeline, causing various problems in the piping. Will be raised.

If the COG contains excessive impurities such as oil mist and water, the temperature non-uniformity in the box annealing furnace causes a huge impact on the product quality and causes equipment shutdown (to stop the operation of the equipment) for import into the dust collector. Will have

Although not shown in the drawing, the electrostatic precipitator is composed of a discharge electrode and a collecting electrode (dust collecting plate), and as a high voltage is applied to the discharge electrode, a large amount of negative ions are generated due to the corona discharge caused by the high voltage, and dust particles in the gas are charged. In addition, it is used to collect and remove dust particles on the dust collecting plate by electric force by electric field.

Application No. 10-2002-0055577 discloses an electrostatic precipitator cleaning device with improved dust collection efficiency.

Embodiments of the present specification relate to an oil and water separation apparatus capable of increasing dust collection efficiency by separating and removing impurities such as oil mist from a gas by an electrostatic precipitator and centrifugal force.

Embodiment of the present specification, the cost and installation cost is reduced due to the structure of the separator for collecting, separating and removing impurities from the gas, and the impurities adsorbed on the porous plate by a scraper to regenerate the porous plate This is related to the oil-water separator which can extend the service life and reduce the maintenance cost due to low failure rate.

According to an aspect of the present invention, the impurities contained in the gas transferred from the gas supply pipe to the first separation device is first separated by the vortex formed inside the first separation device, and the first separation A water / oil separator for separating the impurities contained in the gas passing through the apparatus, wherein the second separator for separating the impurities from the gas passing through the first separator comprises: A housing through which gas from which impurities are primarily separated is introduced; An insulator installed on one inner side of the housing and fixed to one side of the discharge electrode support frame supplied with an arbitrary high voltage from the outside; A discharge electrode accommodated in an inner center and supplied with a high voltage through the insulator support frame of the insulator, and rotatably installed in the housing, and collect impurities on the inner surface by discharge from the discharge electrode; In the rotation, the impurity is separated from the gas by centrifugal force, but the separated impurity is formed of a cone-shaped porous plate whose front end is blocked so that the impurity can be moved to the opening along the inclined plane and the filtered air can be discharged outward through the through hole. Impurity separator; A discharge pipe connected to the discharge port of the housing and discharging the filtered air passing through the second separator to the outside, wherein the operation of the first separator and the second separator is temporarily stopped. In this case, the oil-water separator further comprises a bypass pipe for directly transferring the gas transferred through the gas supply pipe to the outlet pipe outlet side of the second separator without transferring the gas to the first separator. Can be.

Embodiments of the present disclosure configured as described above have the following advantages.

Impurities such as oil mist, water, tar, and the like are separated and removed from the gas by an electrostatic precipitator and centrifugal force, thereby increasing dust collection efficiency, thereby providing practicality and reliability.

In addition, the cost and installation cost can be reduced by simplifying the structure of the separator that collects, separates and removes impurities from the gas, thereby increasing the cost competitiveness in the industry and removing impurities adsorbed on the porous plate by the scraper. By regenerating the perforated plate, the service life can be extended and the economic burden on the user can be reduced by reducing the maintenance cost due to low failure rate.

1 is a schematic diagram of an oil / water separator according to an embodiment of the present specification.
FIG. 2 is a plan view of the oil / water separator shown in FIG. 1.
3 is a cross-sectional view taken along line AA of FIG. 1.
4 is a cross-sectional view taken along line BB of FIG. 2.
5 is a cross-sectional view taken along line CC shown in FIG. 2.
FIG. 6 is a state diagram of use of the oil / water separator shown in FIG. 1.

Hereinafter, with reference to the accompanying drawings will be described in detail the oil-water separator according to a preferred embodiment of the present specification.

1 to 6, the oil-water separator according to one embodiment of the present specification

A gas that is turned due to vortices formed inside the first separator 10 by impurity contained in the gas transferred from the coke oven (not shown) to the first separator 10 through the gas supply pipe 24. In the oil-water separation apparatus for separating the primary from the secondary, and the secondary separation of impurities contained in the gas passing through the first separator 10:

The second separator 11 for secondary separation of impurities (eg, oil mist, water, tar, etc.) from the gas passing through the first separator 10 is

A housing 12 through which the gas from which impurities are primarily separated from gas is introduced through the first separation device 10;

An insulator 13 installed on one side of the housing 12 and fixed to one side of an electrode support frame to which a high voltage is supplied from the outside;

Discharge electrode which is formed in the shape of a cone (the diameter gradually decreases toward the direction away from the opening) blocked by the front end portion, is rotatably installed in the housing 12, and is supplied with a high voltage through the discharge electrode support frame 13a of the insulator 13; (discharge electrode) 14 is accommodated in the inner center, and when a high voltage is applied to the discharge electrode 14 to collect impurities (referred to tar particles, etc.) contained in the gas due to corona discharge on the inner surface ( Impurity from the gas by centrifugal force during rotation by power transmitted through a chain 19 (or belt) connected to the pulley of the drive motor 18), the drive motor 18 Are separated, the separated impurities are moved to the opening along the inclined surface and the filtered air is circumferentially outwardly through the through hole 20a which is perforated over an arbitrary section of the cylindrical portion 20c (consisting of the perforated plate). Kiel release impurity separator 20, the front end portion made of a perforated plate of the cone-shaped blind to;

And a discharge pipe 22 connected to the discharge port 21 of the housing 12 and for discharging the filtered (purified) air passing through the second separator 11 to the outside.

The oil / water separator is disposed between the insulator 13 and the impurity separator 20 so as to be spaced apart from the opening of the impurity separator 20, and the gas flowing into the housing 12 is randomly formed in the opening of the impurity separator 20. It may be provided with a; guider 17 for supplying at a pressure of.

The oil / water separator is provided with a scraper spaced at random intervals from the inner surface of the impurity separator 19 so as to regenerate the impurity separator 20 as the impurities adhered to the impurity separator 20 are separated by friction. 23) (scraper); may be provided.

When the operation of the first separator 10 and the second separator 11 is temporarily stopped, the oil / water separator may not pass the gas transferred through the gas supply pipe 24 to the first separator 10. Instead, the bypass pipe 25 for transferring the discharge pipe 22 of the second separation device 11 directly to the outlet side can be provided.

Oil-water separator,

A drain valve 28 mounted on the bottom surface of the housing 12 so as to be opened and closed;

Impurities (oil mist, moisture), which are jointly connected through a pipe detachably connected to the drain valve 28 and separated from the gas by the rotation of the impurity separator 20, are formed along the inclined surface of the impurity separator 20. An impurity reservoir 29 for storing impurities discharged from the housing 12 through the drain valve 28 when the impurities flow down toward the opening or remain on the bottom surface of the housing 12. Can be.

The impurity reservoir 29 may be equipped with a caster 29a on the bottom of the impurity reservoir 29 so as to be movable when disposing of the impurity collected at a designated place.

The impurity separator 20 may be a scraper 23 or a scraper 23 to dissolve and remove impurities attached to the inner surface of the impurity separator 20 by spraying high-temperature steam (for example, steam at about 170 ° C.). 23) or a steam injection port 30 for supplying high temperature steam to the impurity separator 20 may be provided.

According to the above-described configuration, as the gas transferred from the coke oven (not shown) through the gas supply pipe 24 is transferred into the first separator 10, the blade built in the first separator 10 ( Due to the collision between a) and the gas, vortices are generated in the gas introduced into the first separator 10.

Therefore, the gas transferred to the first separation device 10 is swirled by the vortex generated inside the first separation device 10 by the vortex, and the steam injection port 40 and the discharge port side installed on the inlet side. It is supplied from the outside by the steam injection port 50 installed to adsorb impurities (such as oil mist, moisture, etc.) contained in the gas by steam injected into the first separator 10 to be separated first.

At this time, as the blade (a) is rotated by the conveying force of the gas flowing into the first separation device 10, impurities are separated and removed from the gas that is swirled in the first separation device 10 in a vortex state. Since the technical contents are used in the art, detailed descriptions of these configurations are omitted.

Impurities firstly separated from gas in the first separator 10 are discharged through the outlet 10a of the first separator 10. In other words, the impurities are stored in the storage tank (b) communicated through the pipe to the discharge port (10a), and the impurities collected in the storage tank (b) are disposed of at a designated place. At this time, the storage tank (b) can be easily moved to any place by the caster mounted on the bottom surface.

As described above, the gas from which impurities are first separated in the first separator 10 is separated through the connecting pipe c connecting the first separator 10 and the second separator 11 to communicate with each other. It is conveyed inside the housing 12 of the device 11.

The gas transferred to the housing 12 may secondarily separate impurities contained in the gas by the second separator 11. That is, when a high voltage is applied to the discharge electrode 14 installed inside the housing 12, the impurities of the gas may be collected on the inner surface of the impurity separator 20 by corona discharge (the impurity separator serves as a dust collecting plate). At the same time, when the impurity separator 20 is rotated, impurities that are separated from the gas by centrifugal force may be discharged outward in the circumferential direction.

In detail, a high voltage from the outside may be applied to the discharge electrode 14 via the insulator 13 installed inside the housing 12. That is, since a large amount of negative ions are generated by corona discharge due to the high voltage applied to the discharge electrode 14, impurity particles such as tar in the gas may be collected on the inner surface of the impurity separator 20.

In this case, as the high voltage is applied to the discharge electrode 14, the technology of collecting and removing impurity particles in the gas on the inner surface of the impurity separator 20 belongs to the technology used in the art, and thus, their configuration and operation. Detailed description thereof will be omitted.

On the other hand, when the gas transported inside the housing 12 passes through the guider 17 and is transferred to the inside of the impurity separator 20 in which the front end is blocked, the impurity separator 20 is rotated by driving the driving motor 18. As a result, air from which impurities (oil mist) are separated by centrifugal force passes through the through hole of the impurity separator 20 formed of the porous plate and is discharged to the outside in the circumferential direction (air filtered by the arrow is discharged from the impurity separator 20). The direction of the discharge from).

At this time, impurities such as oil mist separated from the gas flow down toward the opening along the inclined surface formed to be inclined downward toward the opening of the impurity separator 20 (to flow down in the opposite direction to the conveying direction of the gas).

On the other hand, impurities separated from the gas by centrifugal force by the rotation of the impurity separator 20 may adhere to the inner surface of the impurity separator 20 to be fixed.

At this time, the impurity separator 20 is removed by frictional removal of the adherents attached to the inner surface of the impurity separator 20 by the scraper 23 installed to be spaced apart from the inner surface of the impurity separator 20 by an arbitrary distance. You can play it back.

In addition, the high temperature steam from the steam supply (not shown) is sprayed between the scraper 23 and the inner surface of the impurity separator 20 through the steam injection nozzle 30 installed inside the housing 12, the scraper By 23, the fixed matter which is not removed from the impurity separator 20 can be melted and detached.

As described above, impurities that are separated from the gas and move outward in the circumferential direction and flow down toward the opening along the inclined surface of the impurity separator 20 or impurities remaining on the bottom surface of the inside of the housing 12 are bottom surfaces of the housing 12. It may be discharged to the outside of the housing 12 through the drain valve 28 mounted to.

The impurities discharged through the drain valve 28 are discharged to the impurity reservoir 29 through a pipe that is detachably connected to the drain valve 28. Therefore, after separating the pipe from the drain valve 28, the impurity reservoir 29 can be moved to an arbitrary place by the caster 29a mounted on the bottom surface for disposal.

If a failure occurs in the first separation device 10 or the second separation device 11, the first and second separation devices 10 and 11 may be operated by servicing the first and second separation devices 10 and 11. You can stop it temporarily.

At this time, even in a work environment in which gas is continuously transferred through the gas supply pipe 24, the valve V1 provided at the inlet side of the first separator 10 is shut off and the outlet side of the second separator 11 is closed. In the state in which the valve (V2) is installed in the state, the valve (V3) installed on the inlet side of the bypass pipe 25 is opened, so that the COG transferred through the gas supply pipe (24) is separated from the first and second separation devices. Without passing through (10, 11), it is possible to directly transfer to the outlet side of the discharge pipe (22) of the second separation device (11) through the bypass pipe (25).

The gas passing through the first separator 10 and / or the second separator 11 according to one embodiment of the present invention may be, for example, "coke oven gas" (COG). have. The gas supply pipe 24 according to an embodiment of the present invention may be referred to as a "COG supply pipe".

Herein, while the present specification has been described with reference to the preferred embodiments, those skilled in the art may variously change the contents of the present disclosure without departing from the spirit and scope of the present disclosure described in the following claims. It will be appreciated that modifications and variations can be made.

10: first separation device
11: second separator
12: housing
13: Insulator
14: discharge electrode
15: insulator
16: electrostatic precipitator
17: guider
18: Drive motor
19: chain
20: impurity separator
21: outlet
22: discharge pipe
23: scraper
24: gas supply pipe
25: Bypass tube
28: drain valve
29: impurity reservoir
30: steam nozzle

Claims (6)

The impurities contained in the gas transferred from the gas supply pipe to the first separation device are first separated by the vortices formed inside the first separation device, and the impurities contained in the gas passing through the first separation device are secondary. In the oil / water separator to separate:
The second separator for secondary separation of impurities from the gas passing through the first separator,
A housing through which the gas from which impurities are primarily separated flows through the first separation device;
An insulator installed on one side of the housing and fixed to one side of an electrode support frame to which a high voltage is supplied from the outside;
A discharge electrode accommodated in an inner center and supplied with a high voltage through the insulator support frame of the insulator, and rotatably installed in the housing, and collect impurities on the inner surface by discharge from the discharge electrode; In the rotation, the impurity is separated from the gas by centrifugal force, but the separated impurity is formed of a cone-shaped porous plate whose front end is blocked so that the impurity can be moved to the opening along the inclined plane and the filtered air can be discharged outward through the through hole. Impurity separator;
And a discharge pipe connected to the discharge port of the housing and discharging the filtered air passing through the second separator to the outside.
When the operation of the first separation device and the second separation device is temporarily stopped, for transferring the gas transferred through the gas supply pipe directly to the outlet pipe outlet side of the second separation device without transferring the gas to the first separation device. By-pass pipe; oil-water separator further comprises. The method of claim 1,
And a guider positioned between the insulator and the impurity separator so as to be spaced apart from the opening of the impurity separator, and supplying a gas flowing into the housing to the opening of the impurity separator at an arbitrary pressure.
Oil-water separator. The method of claim 1,
And a scraper spaced apart at random intervals with respect to an inner surface of the impurity separator to separate and regenerate impurities fixed in the impurity separator by friction.
Oil-water separator. delete The method of claim 1,
A drain valve mounted to a bottom surface of the housing;
The impurity is separated through a pipe detachably connected to the drain valve, and impurities separated from the gas by the rotation of the impurity separator flow down toward the opening along the inclined surface of the impurity separator or on the bottom surface of the inside of the housing. And an impurity reservoir for storing impurities discharged from the housing through the drain valve when impurities remain.
Oil-water separator. The method of claim 3,
The impurity separator is
And a steam injection port for supplying high temperature steam to the scraper or impurity separator so that impurities fixed on the inner surface of the scraper or impurity separator can be dissolved and detached by high temperature steam injection.
Oil-water separator.

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