KR20180056856A - oil mist separator of plate type - Google Patents

Abstract

The present invention relates to a plate type oil mist separator for adsorbing, separating and removing oil mist from a gas stream containing oil mist,
The plate type oil mist separator according to the embodiment of the present invention
An oil mist separator for separating and adsorbing an oil mist from a gas stream containing oil in a mist state, the oil mist separator comprising:
The separation profile, which is laterally arranged with respect to the flow direction of the gas stream,
A first asymmetrical separation profile and a first symmetrical separation profile extending from a lower end of the first asymmetric separation profile, the first and second asymmetrical separation profiles being repeatedly arranged in an equally spaced relationship in the left and right direction, A first separation profile for introducing the gas stream through the first separation profile,
A second symmetrical separation profile, and a second asymmetric separation profile extending from the lower end of the second symmetrical separation profile, the first and second symmetrical separation profiles being repeatedly arranged between adjacent first separation profiles, The second separation profile defining a passage through which the oil mist-removed gas stream is discharged while the arms maintain an arbitrary spacing relative to the short arm of the first separation profile,
Wherein the arc portion is formed as a layer to change the flow direction of the gas stream to collide with the first and second separation profiles to produce a vortex in the gas stream flowing through the long arm of the neighboring first separation profile, The intermediate arm and the short arm of the first and second separation profiles are spaced at an arbitrary interval in the arc portion of the opposite side separation profile to form a moving path through which the gas stream moves between the adjacent first and second separation profiles And a plate-shaped oil mist separator.

Description

[0001] The present invention relates to a plate type oil mist separator,

The present invention 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, metal working sites are subjected to cutting, turning or grinding processes, and various mineral oils and aqueous or oily detergents are widely used for cooling, lubrication and cleaning in these processing steps.

Mineral oils and detergents are volatilized and scattered along with fine metal microparticles produced in cutting, turning or grinding processes. The particles of metal fine particles and oils and detergents which are volatilized and scattered and floating in the air are generally referred to as "oil mist ".

When an air purifier or an oil mist collecting device is not installed in the workplace, the oil mist is discharged from the workplace as it is through the exhausting facility of the workplace, which is a major factor of air pollution.

The oil mist has a detrimental effect on the working environment even in the workplace, and also causes skin irritation when it comes into contact with the skin of the worker. It also acts as a cause of malfunction such as malfunction or short-circuit of precision machining apparatus such as numerical control machine tools.

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

In a fiber bed filter (or a candle filter), which is a type of filter dust collector, oil mist is caused to collide with a fiber bed and collected by passing a gas containing oil mist horizontally through the fiber bed filter.

The collected oil mist is aggregated to such a degree as to be able to flow downward by gravity while being joined together, and the flowing oil mist is removed through the discharge device under the filter.

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

The above-described oil mist removing apparatus is accompanied with a discharge device or a high-speed rotary drum having a filter and the like, and additional components are installed, resulting in an increase in the manufacturing cost of the device.

Also, the maintenance cost of the apparatus is increased, and problems such as excessive noise and vibration, frequent replacement of the filter due to restriction of the filter area, and the like occur. The treatment efficiency of the apparatus is so low that it can not be used solely for indoor air purification, and the discharged air needs to be reprocessed with a separate air purifier.

A plate type separator for separating liquid from a gas flow is disclosed in Application No. 10-2011-7013839.

The embodiment of the present invention relates to a plate type oil mist separator that is used semi-permanently because a separation profile (or impinger) for adsorbing, separating and removing oil mist is not clogged or exchanged.

Embodiments of the present disclosure relate to a plate type oil mist separator that can reduce the cost of manufacturing it due to the simplification of the separation profile and improve the efficiency of separating and removing oil mist from the gas stream.

The embodiment of the present invention relates to a plate type oil mist separator that can improve the workability of detaching and removing a separation profile because there is no directionality of the separation profile with respect to the moving direction of the oil mist.

The plate type oil mist separator according to the embodiment of the present invention

An oil mist separator for separating and adsorbing an oil mist from a gas stream containing oil in a mist state, the oil mist separator comprising:

The separation profile, which is laterally arranged with respect to the flow direction of the gas stream,

A first asymmetrical separation profile and a first symmetrical separation profile extending from a lower end of the first asymmetric separation profile, the first and second asymmetrical separation profiles being repeatedly arranged in an equally spaced relationship in the left and right direction, A first separation profile for introducing the gas stream through the first separation profile,

A second symmetrical separation profile, and a second asymmetric separation profile extending from the lower end of the second symmetrical separation profile, the first and second symmetrical separation profiles being repeatedly arranged between adjacent first separation profiles, The second separation profile defining a passage through which the oil mist-removed gas stream is discharged while the arms maintain an arbitrary spacing relative to the short arm of the first separation profile,

Wherein the arc portion is formed as a layer to change the flow direction of the gas stream to collide with the first and second separation profiles to produce a vortex in the gas stream flowing through the long arm of the neighboring first separation profile, The intermediate part arm and the short arm of the first and second separation profiles are spaced at an arbitrary interval in the arc part of the opposite side separation profile to form a moving path through which the gas stream moves between the adjacent first and second separation profiles The plate-shaped oil mist separator being characterized in that:

The embodiment of the present invention configured as described above has the following advantages.

As the gas stream including the oil mist is moved along the S-shaped moving path, the oil mist separated from the air is aggregated and free-falled as the vortex is formed, or adsorbed on the surface of the filtration part and flowed down along the filtration part to be removed The efficiency of removing the oil mist is maximized and the separation profile for adsorbing and removing the oil mist is not clogged or exchanged. Therefore, it is economical because it can be used semi-permanently.

In addition, because of the simplified structure of the separation profile, it is possible to reduce the manufacturing cost, thereby realizing practicality and reliability.

Further, since the separation profile provided in the transverse direction with respect to the moving direction of the oil mist does not have the directionality in the back-and-forth direction (the bidirectional property is obtained), it is possible to improve the workability of attaching and detaching the separation profile to the main body.

1 is a perspective view of a separation profile in a plate type oil mist separator according to an embodiment of the present invention;
FIG. 2 is a view showing the disposition of the separation profile shown in FIG. 1;
Fig. 3 is an enlarged view of the main part of the separation profile shown in Fig. 1,
4 is a use state diagram of the separation profile shown in Fig.

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

1 to 4, a plate type oil mist separator according to an embodiment of the present invention includes:

An oil mist separator for separating and adsorbing an oil mist from a gas stream containing oil in a mist state, the oil mist separator comprising:

The separation profile (10), arranged transversely with respect to the flow direction of the gas stream,

A first asymmetrical separation profile 13 having an X-shaped transverse section made up of a long arm 11 and an intermediate arm 12 and a second asymmetrical separation profile 13 having an intermediate arm 14 , A first symmetrical separation profile 16 having an X-shaped transverse section consisting of a short arm 15 (merged with the middle arm 12 of the first asymmetrical separation profile 13) and a short arm 15, A first separation profile (17) which is repeatedly arranged with equal spacing and through which the gas stream flows through the gap between the long arms (11) of the neighboring first asymmetrical separation profiles (13, 13a)

A second symmetrical separation profile 20 having an X-shaped transverse section consisting of a short arm 18 and an intermediate arm 19 and a second symmetrical separation profile 20 extending from the lower end of the second symmetrical separation profile 20, And a second asymmetrical separation profile 23 having a cross-section in the form of an X-shaped cross-section consisting of a long arm 22 joined to an intermediate arm 19 of a second symmetrical separation profile 20, And the long arms 22 and 22a opposed to each other are arranged at an arbitrary interval with respect to the short arm 15 of the first separation profile 17 so that the oil mist is removed And a second separation profile (25) forming a passage (24) through which the gas stream is discharged,

The gas stream collides with the first and second separation profiles 17 and 25 to produce a vortex in the gas stream flowing through the long arms 11 of the neighboring first separation profiles 17 and 17a, The intermediate arms 12, 14, 19, 21 and the short arms 15, 18 of the first and second separation profiles 17, (28, 29) in which the gas stream is moved in one direction between the first and second separation profiles (17, 25) which are adjacent to each other in the left and right direction while an arbitrary interval is maintained in the arc portions (26, 27) ).

The cross section to which the oil mist is contacted is enlarged so that the longitudinal adsorption section 30 for promoting the adsorption of the oil mist is provided on the inner side of the circular arc sections 26 and 27 of the first and second separation profiles 17 and 25, As shown in FIG.

The adsorption section 30

Either semicircular, trapezoidal or elliptical shapes may be formed in a block shape or a concave shape.

The ends of the short arms 15,18, the intermediate arms 12,14,19,21 and the long arms 11,22 of the first and second separation profiles 17,25

May be rounded to prevent interference with the flow of the gas stream to stagnate.

The movement passages 28, 29 formed between the adjacent first and second separation profiles 17, 25 so that the gas stream is moved in one direction can be formed in an S shape.

According to the above-described configuration, a gas stream including oil mist discharged from a semiconductor manufacturing factory or the like is supplied to a charging port 110 formed in the main body 100 through a duct (not shown). The gas stream supplied to the inlet 110 approaches the separation profile 10 formed in a plate shape by driving the turbine 120 inside the main body 100 in the transverse direction.

In this case, the technical content of supplying the gas stream supplied to the inlet 110 to the separation profile 10 by driving the turbine 120 will be described in the description of the related art, do.

That is, the gas stream passes through the gap between the long arms 11, 11a of the first asymmetrical separation profile 13, 13a of the first separation profile 17, 17a adjacent in the left-right direction to form the second separation profile A portion of the gas stream (referring to the gas stream being moved in the left direction as viewed in the figure) flows into the long arm 18 of the first separation profile 17, (26) formed in the long arm (11) of the first separation profile (17) and the second separation profile (26) formed in the first separation profile (17) after passing through the passage between the first separation profile (11) (28) formed by the short arm (18) of the piston (25).

At the same time, a part of the gas stream (referred to as a gas stream moved in the right direction in the drawing) introduced into the branching portion a of the short arm 18 of the second separation profile 25 is separated from the first separation profile 17a After passing through the passage between the long arm 11a of the first separation profile 17a and the short arm 18 of the second separation profile 25 and then passing through the arc portion 26a formed in the long arm 11a of the first separation profile 17a Is introduced into the inlet side of the moving passage 29 formed by the short arm 18 of the second separation profile 25.

When the gas stream is introduced into the inlet side of the transfer passage 28 formed between the first and second separation profiles 17 and 25 as described above, the gas stream is introduced into the intermediate arms 12, 14 and a circular arc portion 27 formed on the upper portion of the second symmetrical separation profile 20 and a circular arc portion 26 formed in the lower portion of the first symmetrical separation profile 16 and a second separation A movement path 28 between the intermediate arms 19 and 21 of the profile 25 and a circular arc 15 formed in the lower part of the short arm 15 and the second asymmetric separation profile 23 of the first separation profile 17, (22) of the second asymmetrical separation profile (23) after passing through the first separation profile (17) and the transfer passage (28) 24 and is discharged to the outside through the gap between the long arms 22, 22a of the second asymmetrical separation profile 23, 23a adjacent to the left and right direction.

During the movement of the gas stream along the S-shaped travel passage 28 formed between the first and second separation profiles 17 and 25 as described above, the first and second separation profiles 17, A vortex is generated as the gas stream is rotated in the moving passage 28 by collision with the gas-liquid contact holes 26 and 27. The oil mist separated from the air by the vortex generated in the moving passage 28 is entangled with each other to enlarge the particles and the oil mist particles are aggregated and a part of the aggregated oil mist is freely dropped by gravity.

At the same time, a part of the oil mist is sucked and discharged by the arc portions 26 and 27 formed as layers on the first and second separation profiles 17 and 25 by the gas stream swirling in the movement passage 28. The oil mist adsorbed and flowing on the inner surfaces of the first and second separation profiles 17 and 25 flows into the oil reservoir (not shown) provided at the lower end of the separation profile 10, is stored and then reprocessed, .

At this time, the adsorption portions 30 in the longitudinal direction for promoting adsorption of the oil mist protruding from the circular arc portions 26 and 27 of the first and second separation profiles 17 and 25 (for example, (Formed semicircularly on the outer surface of the arc portion 30 of the first and second separation membranes 17 and 25) to increase the swirl of the gas stream in the movement passages 28 and 29, It is possible to improve the dust collecting efficiency by separating and adsorbing the oil mist from the gas stream and removing it.

In addition, as the ends of the short arms 15, 018 and the intermediate arms 12, 14 (19, 21) of the first and second separation profiles 17, 25 are rounded, It is possible to increase the swirl in the moving passages 28 and 29 by preventing the stagnation of the flowing gas stream by interfering with it. As a result, the dust collection efficiency for separating and removing the oil mist from the gas stream can be improved.

As described above, during the movement of the gas stream along the movement passages 28, 29 of the first and second separation profiles 17, 25, the air mist removed by the vortex formed in the movement passages 28, After passing through the space portion b of the first and second separation profiles 30, the gap between the long arms 22 and 22a of the adjacent second separation profiles 25 and 25a and the duct ). ≪ / RTI >

On the other hand, a part of the gas stream flowing through the gap between the long arms 11 and 11a of the neighboring first separation profiles 17 and 17a flows into the branched branch 18 of the branched short arm 18 of the second separation profile 25, (hereinafter referred to as a gas stream which is moved in the right direction in the figure) after passing through the first separation profile 25a and the second separation profile 25b, The stream is directed to the intermediate arms 12a and 14a of the arcuate portion 27 and the first separation profile 17a of the second symmetrical separation profile 20 and the intermediate arms 19 and 21 of the second separation profile 25, Is formed by the arcuate portion 26a of the first symmetrical separation profile 16a and the short arm 15a of the second symmetrical separation profile 16 and the arcuate portion 27 of the second asymmetric separation profile 23 And passes through the moving passage 29 in order.

Thereby, during the movement of the gas stream along the S-shaped movement passage 29, the oil mist is separated from the gas stream by the vortex generated by the rotation of the gas stream inside the movement passage 29, The technical content to be removed is substantially the same as the technical content of removing the oil mist from the gas stream by separation and adsorption by the vortex formed in the S-shaped moving passage 28 described above, Will not be described in detail.

While the present invention has been described with reference to preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the following claims It will be understood that the invention may be varied and changed without departing from the scope of the invention.

10; Separation profile 11; Long arm
12; Intermediate arm 13; The first asymmetric separation profile
14; Intermediate arm 15; Short arm
16; A first symmetrical separation profile 17; The first separation profile
18; A short arm 19; Middle arm
20; A second symmetrical separation profile 21; Middle arm
22; A long arm 23; The second asymmetric separation profile
24; Passage 25; The second separation profile
26; A circular arc portion 27; Arc part
28; A moving passage 29; Moving passage
30; Absorption portion

Claims (5)

An oil mist separator for separating and adsorbing an oil mist from a gas stream containing oil in a mist state, the oil mist separator comprising:
The separation profile, which is laterally arranged with respect to the flow direction of the gas stream,
A first asymmetrical separation profile and a first symmetrical separation profile extending from a lower end of the first asymmetric separation profile, the first and second asymmetrical separation profiles being repeatedly arranged in an equally spaced relationship in the left and right direction, A first separation profile for introducing the gas stream through the first separation profile,
A second symmetrical separation profile and a second asymmetric separation profile extending from the lower end of the second symmetrical separation profile and being repeatedly arranged between adjacent first separation profiles, The second separation profile defining a passage through which the oil mist-removed gas stream is discharged while the arms maintain an arbitrary spacing relative to the short arm of the first separation profile,
Wherein the arc portion is formed as a layer to change the flow direction of the gas stream to collide with the first and second separation profiles to produce a vortex in the gas stream flowing through the long arm of the neighboring first separation profile, The intermediate arm and the short arm of the first and second separation profiles are spaced at an arbitrary interval in the arc portion of the opposite side separation profile to form a moving path through which the gas stream moves between the adjacent first and second separation profiles Wherein the plate-shaped oil mist separator is a plate-shaped oil mist separator. The method according to claim 1,
Wherein a longitudinally adsorbing portion for increasing the adsorption of the oil mist is formed repeatedly on the inner surface of the arc portion of the first and second separation profiles by enlarging a cross section where the oil mist is contacted. The apparatus according to claim 2, wherein the adsorption unit
Wherein one of the semicircular, trapezoidal, and elliptical shapes is formed in a block shape or a concave shape. 2. The apparatus of claim 1, wherein the ends of the short arm, middle arm and long arm of the first and second separation profiles
And is rounded to prevent interference with the flow of the gas stream to stagnate. The method according to claim 1,
Wherein the gas passage is formed between the adjacent first and second separation profiles so that the gas passage is formed in an S-shape.

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