KR101977368B1 - oil mist separator of plate type - Google Patents

Abstract

Published information relates to a plate-type oil mist separator for adsorbing, separating and removing oil mist from a gas stream containing oil mist,
Plate-type oil mist separator according to an embodiment of the present specification
In an oil mist separator for separating and adsorbing oil mist from a gas stream containing oil in a mist state:
The separation profile arranged transverse to the flow direction of the gas stream,
The first separation profile is formed by forming a heat at equal intervals in the left and right direction, the gas stream is introduced through the neighboring profile, the first bent portion for generating a vortex in the gas stream facing the opening and,
It is formed by forming a row in the left and right directions to form a zigzag form to maintain a random interval with respect to the first separation profile, the gas from which the oil mist is removed is discharged through the neighboring profile, to create a vortex in the gas stream The second bent portion has a second separation profile formed to face the opening,
When the gas stream flowing through between the adjacent first separation profiles enters the vortex chamber defined by the first and second bends, the vortex generated by the rotation of the gas stream in the vortex chamber Part of the oil mist which is agglomerated by the free fall, and part of the oil mist is adsorbed to the inner surface of the first and second separation profile flows down provides a plate-type oil mist separator.

Description

Oil mist separator of plate type

The present specification relates to a separator, and more particularly, to a plate-type oil mist separator for adsorbing, separating and removing oil mist from a gas stream containing oil mist.

In general, in the metal working site, a cutting process, a turning process or a grinding process is performed, and various mineral oils and aqueous or oil detergents are widely used for cooling, lubrication, and washing in such processing processes.

Mineral oils and detergents are volatilized and scattered together with the fine metal fine particles produced in the cutting and turning or grinding processes. As such, metal particles and particles of oils or detergents that are volatilized and scattered and float in the air are commonly referred to as "oil mist".

If an air purifier or oil mist collecting device is not installed in the workplace, the oil mist is discharged out of the workplace as it is through the exhaust facility of the workplace, which is a big factor of air pollution.

Oil mist not only causes deterioration of the working environment in the workplace, but also causes dermatitis and the like when contacted with the skin of an operator. It also acts as a cause of malfunctions such as malfunctions or short circuits in precision machining equipment such as numerically controlled machine tools.

In the electrostatic precipitator, which is a type of oil mist removing device, when a high voltage is applied to the discharge electrode, a large amount of negative ions are generated by corona discharge caused by the high voltage, and the dust in the gas is charged. It is collected in the dust collecting plate. The fine particles are removed by separating the dust particles collected in the dust collecting plate from the dust collecting plate by mechanical impact.

In a fiber bed filter (or candle filter) device, which is a type of filter dust collector, the oil mist collides with the fiber bed and is collected as the gas containing the oil mist passes through the fiber bed filter in a horizontal direction.

The collected oil mists coalesce to one another and aggregate to such a size that they can flow downward by gravity, and the oil mists that flow down are removed through the discharge device under the filter.

The centrifugal filter type air purifier uses a method of filtering the oil mist through the filter using centrifugal force generated by rotating the drum having the blower blade and the filter on the outer circumferential surface at high speed.

The above-described oil mist eliminator is equipped with a discharge device or a high speed rotating drum having a filter and the like, which results in an increase in the manufacturing cost of the apparatus.

In addition, maintenance costs of the apparatus are increased, and problems such as excessive replacement of the filter due to excessive noise and vibration and limitation of the filter area occur. As the treatment efficiency of the device is low, it cannot be used alone for indoor air purification, and a problem arises in that the discharged air must be reprocessed with a separate air purifier.

Application number 10-2011-7013839 discloses a plate-shaped separator for separating liquid from gas flow.

Embodiments of the present specification relate to a plate-type oil mist separator in which a separation profile (or impinger) for adsorbing and separating oil mist can be used semi-permanently without clogging or exchange.

Embodiments herein relate to plate-type oil mist separators that enable cost savings due to the simplified structure of the separation profile and improve the efficiency of separating and removing oil mist from air.

Embodiments of the present specification relate to a plate-type oil mist separator that can improve the workability of detaching and separating the separation profile since there is no directivity of the separation profile with respect to the moving direction of the oil mist.

Plate-type oil mist separator according to an embodiment of the present specification

In an oil mist separator for separating and adsorbing oil mist from a gas stream containing oil in a mist state:

The separation profile arranged transverse to the flow direction of the gas stream,

The first separation profile is formed by forming a heat at equal intervals in the left and right direction, the gas stream is introduced through the neighboring profile, the first bent portion for generating a vortex in the gas stream facing the opening and,

It is formed by forming a row in the left and right directions to form a zigzag form to maintain a random interval with respect to the first separation profile, the gas from which the oil mist is removed is discharged through the neighboring profile, to create a vortex in the gas stream The second bent portion has a second separation profile formed to face the opening,

When the gas stream flowing through between the adjacent first separation profiles enters the vortex chamber defined by the first and second bends, the vortex generated by the rotation of the gas stream in the vortex chamber Part of the oil mist which is agglomerated by the free fall, and part of the oil mist is adsorbed to the inner surface of the first and second separation profile flows down provides a plate-type oil mist separator.

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

When the air containing the oil mist flows into the vortex chamber, the oil mist separated from the air agglomerates and free-falls as it forms the vortex, or is adsorbed on the surface of the filtration unit to be removed by flowing down the filtration unit to remove the oil mist. It is economical because it can be used semi-permanently because the separation profile that absorbs and removes oil mist is not maximized and efficiency is maximized.

In addition, since the structure of the separation profile is simplified, the cost and cost are reduced, thereby bringing practicality and reliability.

In addition, since there is no directionality in the front-back direction of the separation profile provided laterally with respect to the moving direction of the oil mist (it has bidirectionality), the workability of attaching and detaching the separation profile to the main body can be improved.

1 is a perspective view of a separation profile in a plate-type oil mist separator according to one embodiment of the present specification,
Figure 2 shows the arrangement of the separation profile shown in Figure 1,
Figure 3 is an enlarged view of the main portion of the separation profile shown in Figure 1,
4 is a state diagram of use of the separation profile shown in FIG.

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

1 to 4, the plate-type oil mist separator according to one embodiment of the present specification

In an oil mist separator for separating and adsorbing oil mist (refering to rough particles of about 30-50 μm in size) from a gas stream containing oil in a mist state:

Separation profile 10 arranged transverse to the flow direction of gas stream A (e.g., formed of stainless steel or ceramic material in view of corrosion resistance and durability, and having an arbitrary length by extrusion molding Can be made),

A semicircular cross-sectional structure is formed to form a row at equal intervals in left and right directions, and a gas stream flows in between adjacent profiles, and a first bent portion 20 for generating a vortex in the gas stream is opposite to the opening. The first separation profile 30 (for example, arranged in a block shape based on the moving direction of the gas stream),

The semi-circular cross-sectional structure is formed to form a zigzag shape to maintain a random interval with respect to the first separation profile 30 to form a row in the left and right directions, the gas from which the oil mist is removed is discharged through the neighboring profile, the gas stream With a second separation profile 50 (e.g., arranged in a concave shape relative to the direction of movement of the gas stream) in which a second bend 40 for creating a vortex is formed opposite the opening,

When the gas stream flowing through between the adjacent first separation profiles 30 enters the swirl chamber 60 formed by the first and second bends 20 and 40, the vortex chamber 60 Some of the oil mist, which is agglomerated by the vortices generated by the rotation of the gas stream, is free-falling, and the portion of the oil mist is adsorbed to the inner surfaces of the first and second separation profiles 30 and 50 and flows down.

The longitudinal adsorption part 70 may be repeatedly formed on the inner side or the outer side of the first and second separation profiles 30 and 50 to enlarge the cross-sectional area in which the oil mist is contacted to increase the adsorption of the oil mist.

Adsorption unit 70 may be formed in any one of a semi-circular, trapezoidal, elliptical shape block shape, or concave shape.

The ends of the first and second bends 20 and 40 may be rounded to prevent stagnation by interfering with the flow of the gas stream in the vortex chamber 60.

Concave formed on the inner side of the first and second bent portions 20 and 40 to increase the rotational force of the gas stream by colliding with the gas stream entering the vortex chamber 60 to change the moving direction of the gas stream. It may be provided with a bending portion 80 of the form.

According to the above-described configuration, the gas stream including the oil mist discharged from the semiconductor manufacturing factory is supplied to the inlet 140 formed in the main body 130 through a duct (not shown). The gas stream supplied to the inlet 140 is laterally approached to the separation profile 10 formed in the form of a plate by driving the turbine 150 inside the body 130.

At this time, since the technical information of supplying the gas stream supplied to the inlet 140 to the separation profile 10 by the driving of the turbine 150 will be referred to as technical information used in the art, a detailed description of these configurations is omitted. do.

That is, when the gas stream enters the space portion a of the second separation profile 50 through the gap between the outer surfaces of the adjacent first separation profile 30, as shown in FIG. A portion of the gas stream moved in the left direction passes through the passage 90 between the first bend 20 of the first separation profile 30 and the inner surface of the second separation profile 50. It is introduced into the vortex chamber 60 formed by the first bent portion 20 of the first separation profile 30 and the second bent portion 40 of the second separation profile 50.

At the same time, as shown in FIG. 3, a portion of the gas stream (referring to the gas stream moving in the right direction on the drawing) is the first bent portion 20a and the second separation profile 50 of the first separation profile 30a. Vortex formed by the first bent portion 20a of the first separation profile 30a and the second bent portion 40 of the second separation profile 50 after passing through the passage 100 between the inner sides. Flows into the chamber 60a.

As described above, when the gas stream enters the vortex chamber 60, vortices are generated as the gas stream is rotated in the vortex chamber 60 by collision with the first and second bent portions 20 and 40. The oil mist separated from the air by the generated vortex is entangled with each other, and the particles become larger, and the oil mist particles are agglomerated and some of the aggregated oil mist is freely dropped by gravity.

At the same time, a portion of the oil mist is adsorbed to the inner surfaces of the first and second separation profiles 30 and 50 by the gas stream swirling in the vortex chamber 60. The oil mist adsorbed to the inner surfaces of the first and second separation profiles 30 and 50 flows into and is stored in an oil storage unit (not shown) installed at the lower end of the separation profile 10, and then reprocessed or disposed of. Can be.

At this time, the longitudinal adsorption portion 70 (for example, inside the first and second separation profiles) for enhancing the adsorption of oil mist protruding from the inner or outer surfaces of the first and second separation profiles 30 and 50. Protruding in a semicircular shape on the side) to increase the vortex of the gas stream in the vortex chamber 60, thereby separating and adsorbing the oil mist from the gas stream by means of the first and second separation profiles 30,50. It is possible to improve the dust collection efficiency.

In addition, since the end portions of the first and second bent portions 30 and 50 forming the vortex chamber 60 are rounded, it is possible to prevent stagnation by interfering with the flow of the gas stream in the vortex chamber 60. Vortex may be increased in the vortex chamber 60. This improves the dust collection efficiency of separating and removing oil mist from the gas stream.

In addition, the gas stream collides with the bend 80 in the vortex chamber 60 by a concave bent portion 80 formed on the inner side surfaces of the first and second bent portions 30 and 50. As the direction of travel is diverted, it is possible to increase the rotational force of the gas stream in the vortex chamber 60 to increase the vortex. This improves the dust collection efficiency of separating and removing oil mist from the gas stream.

As described above, the air in which the oil mist is removed by the vortex chamber 60 formed by the first and second bent portions 20 and 40 of the first and second separation profiles 30 and 50 is the first separation profile. After passing through the space b of 30, it may be discharged to the outside through a passage 110 and a duct (not shown) between the outer surfaces of the adjacent second separation profiles 50 and 50a.

On the other hand, when the gas stream enters the space portion a of the second separation profile 50 through a gap between the outer surfaces of the adjacent first separation profile 30, the gas stream moves in the right direction on the drawing. Gas stream) passes through the passage 100 between the first bend 20a of the first separation profile 30a and the inner side of the second separation profile 50, and then the first separation profile 30 Flows into the vortex chamber 60a formed by the first bent portion 20a and the second bent portion 40 of the second separation profile 50.

For this reason, the technical content which isolate | separates and removes oil mist from a gas stream by adsorption | suction which generate | occur | produces by rotation of a gas stream in the vortex chamber 60a is mentioned above. The separation and adsorption of the oil mist from the gas stream is substantially the same as the description thereof, and thus detailed descriptions of their construction and operation are omitted.

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; Separation profile
20; 1st bending part
30; First separation profile
40; 2nd bend
50; Second separation profile
60; Vortex chamber
70; Adsorption part
80; Fold
90,100,110,120; Passage
a, b; Space

Claims (5)

In an oil mist separator for separating and adsorbing oil mist from a gas stream containing oil in a mist state:
The separation profile arranged transverse to the flow direction of the gas stream,
A semicircular cross-sectional structure is formed to form heat at equal intervals in left and right directions, and the gas stream is introduced through adjacent profiles, and a first bent portion for generating a vortex in the gas stream is formed to face the opening. The first separation profile,
The semi-circular cross-sectional structure is formed to form a zigzag shape to maintain an arbitrary interval with respect to the first separation profile, and is formed in rows in the left and right directions, and gas from which oil mist is removed is discharged through the neighboring profiles. A second separation profile, in which a second bend for generating a vortex is formed opposite the opening,
When the gas stream flowing through between the adjacent first separation profiles enters the vortex chamber defined by the first and second bends, the vortex generated by the rotation of the gas stream in the vortex chamber A portion of the oil mist that is agglomerated by the free fall, and a portion of the oil mist is adsorbed to the inner surface of the first and second separation profiles to flow down,
It is characterized in that the longitudinal adsorption portion for increasing the adsorption of the oil mist by increasing the cross-sectional area in contact with the oil mist is repeatedly formed on the inner side or the outer side of the first, second separation profile
The ends of the first and second bent portions are formed round to prevent stagnation by interfering with the flow of the gas stream in the vortex chamber,
A concave direction changer formed on the inner side of the first and second bent portions so as to collide with the gas stream flowing into the vortex chamber to change the moving direction of the gas stream to increase the rotational force of the gas stream; Plate-type oil mist separator characterized in that it comprises.
delete The method of claim 1, wherein the adsorption unit
Plate-shaped oil mist separator, characterized in that any one of a semi-circular, trapezoidal, elliptical shape is formed in a block shape or concave shape. delete delete

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