JP5375524B2 - Oil mist separator - Google Patents

Abstract

The separator (11) has a housing (12) comprising an inlet port (13), an outlet port (14) and a passage (15). An orifice (22) is provided in a bottom wall (12a) of the housing, and an impact plate (17) is provided at an upper wall (12b) of the housing in a point downstream to a filter (16). A gap (18) is formed between the bottom wall and the plate, and another gap (20) is formed between a distal section of the filter and the upper wall in proximity to a proximal end of the plate. The filter comprises lower and upper half sections (16a, 16b) that are arranged in a different manner.

Description

  The present invention relates to an oil mist separator for removing oil mist contained in blow-by gas as droplets in a housing provided on an engine cylinder head cover or the like.

  When blow-by gas generated during the operation of an automobile engine returns to the intake system while containing oil mist, not only is oil consumed, but the oil mist adheres to intake system components such as the throttle and intake valves. There is a risk of accumulating and causing defects. Therefore, the oil mist is removed by the oil mist separator, and only the gas component is recirculated to the intake passage such as an intake manifold using the negative pressure of the engine and burned. As this type of oil mist separator, a filter type oil mist separator is known in which a filter is disposed in a blow-by gas flow path, and oil mist in the blow-by gas is removed by the filter.

  As a filter constituting this type of oil mist separator, for example, a cylindrical oil mist separator element having a three-layer structure including at least an upstream layer, a midstream layer, and a downstream layer is known (see Patent Document 1). That is, the upstream layer is composed of a nonwoven fabric composed of polyester composite fibers, the midstream layer is composed of glass fiber aggregates, and the downstream layer is composed of nonwoven fabrics composed of polyester composite fibers. And it prevents that the position of a fiber fluctuates by the influence of a gas flow, or the density nonuniformity of a fiber layer generate | occur | produces.

  Further, an annular space is formed by the casing and the exhaust pipe, the upper part of the annular space is connected to the inlet, the upper part of the hole inside the exhaust pipe is connected to the outlet, the swirl chamber is provided below the annular space, and the exhaust A gas-liquid separator in which a filter is filled in a hole inside the pipe has been proposed (see Patent Document 2). This filter is formed so that its density is coarser to finer from the inlet side to the outlet side, and the flow path area filling the filter is widened from the inlet side to the outlet side. And it captures from large mist to minute mist to improve the separation efficiency of gas and liquid.

JP 2004-160328 A (pages 2 and 3) JP 2004-243235 A (second page)

  However, in the filter described in Patent Document 1 or 2, since the oil mist having a large particle diameter and the oil mist having a small particle diameter pass through the filter in a mixed state, clogging is likely to occur in the filter. That is, in the filter of Patent Document 1, oil mist having a large particle diameter is easily trapped in the upstream layer and the midstream layer, so that the filter is easily clogged in those portions, and the entire filter may be blocked. When this blockage occurs, the gas does not flow through the filter, so that the oil mist having a small particle diameter cannot be sufficiently separated, and the oil mist separation efficiency is deteriorated.

  Also in the filter of Patent Document 2, oil mist having a large particle diameter is likely to be trapped in a portion having a large density on the inlet side, and therefore, the filter is likely to be clogged on the inlet side and may be clogged. For this reason, gas stops flowing in the filter as in Patent Document 1, and oil mist having a small particle diameter cannot be separated efficiently.

  Therefore, the object of the present invention is to effectively separate and capture both the large particle size oil mist and the small particle size oil mist from the gas flow, and improve the oil mist separation efficiency. It is an object to provide an oil mist separator that can be used.

In order to achieve the above object, an oil mist separator according to claim 1 is provided with an inlet and an outlet for an oil mist-containing gas in a housing for separating the oil mist contained in the oil mist-containing gas. Forming a flow path through which the oil mist-containing gas flows from the inflow port to the outflow port, and a filter for separating the oil mist contained in the oil mist-containing gas is disposed across the flow path and separated by the filter A discharge hole for discharging the generated oil is provided in the bottom wall of the housing. A baffle plate is provided on the inner wall surface of the housing with an interval on the upstream side of the filter, and a first gap is formed between the other inner wall surface facing the inner wall surface and the baffle plate. A second gap is formed between the end of the filter on the base end side of the plate and the inner wall surface of the housing, and the end on the second gap side of the filter is formed wider than the base end side in the gas flow direction. In addition, the second gap side of the filter is formed at a higher density than the base end side.

  The oil mist separator according to a second aspect of the present invention is the oil mist separator according to the first aspect, wherein the baffle plate is formed downward from the upper wall of the housing and is formed between the lower end of the housing and the bottom wall of the housing. A gap is formed, the filter is provided on the bottom wall of the housing, and the second gap is formed between the upper end of the filter and the upper wall.

An oil mist separator according to a third aspect of the invention is characterized in that, in the invention according to the first or second aspect, the second gap is formed narrower than the first gap.
The oil mist separator according to a fourth aspect of the present invention is the invention according to any one of the first to third aspects, wherein the second wall is provided with an auxiliary wall so that the inner wall surface of the housing faces the end surface of the filter. A filter is provided.

  An oil mist separator according to a fifth aspect of the present invention is the invention according to any one of the first to fourth aspects, wherein the inner wall surface of the housing in the second gap is uneven so as to face the end surface of the filter. A portion is provided.

  In the oil mist separator of the present invention, the gas flow is increased in the first gap, and the oil mist having a large particle diameter passes through the first gap due to its inertia, collides with the filter, and adheres to and is separated. . On the other hand, the oil mist having a small particle diameter with a low flow velocity passes through the first gap and is separated by adhering to the filter in that portion when passing through the second gap.

According to the present invention, the following effects can be exhibited.
According to the oil mist separator of the present invention, both the oil mist having a large particle diameter and the oil mist having a small particle diameter can be effectively separated and captured from the gas flow, and the separation efficiency of the oil mist can be improved. It is possible to suppress clogging of the filter.

The longitudinal cross-sectional view which shows the oil mist separator in 1st Embodiment. It is sectional drawing in the 2-2 line of FIG. 1, Comprising: The cross-sectional view which shows an oil mist separator. (A) And (b) is principal part sectional drawing which shows the oil mist separator of 2nd Embodiment. (A) And (b) is principal part sectional drawing which shows the oil mist separator of 3rd Embodiment. The principal part sectional view showing the oil mist separator of a 4th embodiment. (A) And (b) is principal part sectional drawing which shows the oil mist separator as another example. The principal part sectional drawing which shows another example of the oil mist separator of this invention. The principal part sectional drawing which shows another example of the oil mist separator of this invention. The principal part sectional drawing which shows another example of the oil mist separator of this invention. The principal part sectional drawing which shows another example of the oil mist separator of this invention.

(First embodiment)
Hereinafter, a first embodiment of an oil mist separator according to the present invention will be described in detail with reference to FIGS. 1 and 2.

  As shown in FIGS. 1 and 2, an oil mist separator 11 for recovering oil from oil mist in blow-by gas is provided on a cylinder head cover 10 provided in a cylinder block of the engine. The housing 12 of the oil mist separator 11 is formed in a square tube shape, and an inlet 13 for introducing blowby gas is provided on the bottom wall 12a, and an outlet 14 for exhausting blowby gas is provided on the upper wall 12b. Is provided. Accordingly, a blow-by gas passage 15 through which blow-by gas flows from the inlet 13 toward the outlet 14 is formed in the housing 12 as indicated by arrows in the figure. The bottom wall 12a of the housing 12 is formed integrally with the cylinder head cover 10.

  A filter 16 for capturing oil mist in the blow-by gas by adhering to the central position in the flow direction of the blow-by gas in the housing 12 and separating it into oil droplets to separate and recover the oil crosses the blow-by gas flow path 15. It is fixed in a filter fixing frame (not shown). An upstream side of the filter 16 is spaced downward from the filter 16 so that the baffle plate 17 has a predetermined first gap 18 between the inner wall surface of the upper wall 12b of the housing 12 and the inner wall surface of the bottom wall 12a. It is fixed to.

  On the other hand, a second gap 20 formed narrower than the first gap 18 is formed between the upper end of the filter 16 and the inner wall surface of the upper wall 12 b of the housing 12. The oil mist 21 having a small particle diameter at a flow velocity that has passed through the first gap 18 passes through the second gap 20.

  A circular oil discharge hole 22 is formed through the bottom wall 12 a of the housing 12 on the downstream side of the filter 16. By providing the oil discharge hole 22 in the stagnation region of the blowby gas flow at a position immediately downstream of the filter 16 in this way, the oil accumulated in the lower end portion of the filter 16 is not obstructed by the flow of the blowby gas. 22 is discharged.

  The filter 16 has a different structure between the lower half 16a and the upper half 16b, and the lower half 16a is formed of fibers having a large fiber diameter and a low density so that the oil mist 19 having a large particle diameter can be easily captured. The upper half portion 16b is formed with high density fibers with a small fiber diameter so that the oil mist 21 with a small particle diameter can be easily captured. By using a combination of the filters 16 having different properties as described above, the oil mist 19 having a large particle diameter can be classified and captured, and then the oil mist 21 having a small particle diameter can be captured. The separation efficiency can be increased.

Next, the operation of the oil mist separator 11 configured as described above will be described.
The blow-by gas introduced into the housing 12 from the inlet 13 of the housing 12 of the oil mist separator 11 is blocked by the baffle plate 17 fixed downward from the upper wall 12b of the housing 12 and flows downward. At this time, the oil mist 19 having a large particle diameter collides with the inner surface of the housing 12 and the baffle plate 17 and is captured by the inner surface and the baffle plate 17 to be separated from the gas flow. The captured oil mist aggregates into oil droplets and falls on the bottom wall 12a of the housing 12. The gas flowing downward from the position of the baffle plate 17 passes through the first gap 18. At this time, the gas flow is increased. The flow velocity difference between the oil mist 19 having a large particle diameter and the oil mist 21 having a small particle diameter becomes large.

  Therefore, the oil mist 19 having a large particle diameter and a high flow velocity that has passed through the first gap 18 collides with the lower half portion 16a of the filter 16 due to inertial force. At this time, since the lower half portion 16a of the filter 16 is coarsely formed of fibers having a large fiber diameter, the oil mist 19 having a large particle diameter adheres to the lower half portion 16a of the filter 16 and gradually enlarges to oil droplets. (Oil). The oil that has been made into oil droplets reaches the lower end of the filter 16 due to its own weight and accumulates there.

  On the other hand, the oil mist 21 having a small particle diameter rises from the first gap 18 and passes through the upper half 16b of the filter 16, and the upper half 16b is densely formed with fibers having a small fiber diameter. The oil mist 21 is captured by the upper half 16b. Further, the gas flow including the oil mist 21 having a small particle diameter rises between the filter 16 and the baffle plate 17 and tries to pass through the second gap 20 between the upper end portion of the filter 16 and the upper wall 12b of the housing 12. To do. At that time, an oil mist 21 having a small particle diameter passing through the narrow second gap 20 is captured by the upper end portion of the filter 16. The oil mist 21 having a small particle diameter captured by the upper half portion 16b of the filter 16 becomes oil droplets and descends in the filter 16 by its own weight.

  The oil accumulated at the lower end of the filter 16 is discharged from the oil discharge hole 22 located immediately downstream of the filter 16 together with the oil from the baffle plate 17 and the like. At this time, the oil in the filter 16 can be guided to the oil discharge hole 22 by the wind pressure of the blow-by gas flow flowing into the filter 16. Therefore, the oil accumulated at the lower end of the filter 16 can be quickly discharged into the cylinder head cover 10 from the oil discharge hole 22. On the other hand, the blow-by gas that has passed through the filter 16 is exhausted from the outlet 14 with the oil mist removed, and is returned to the intake manifold or the like for combustion.

The effects exhibited by the first embodiment described above will be collectively described below.
(1) In the oil mist separator 11 of the first embodiment, a baffle plate 17 is provided on the upstream side of the filter 16, and a first gap 18 is formed between the baffle plate 17 and the bottom wall 12 a of the housing 12. In addition, a second gap 20 is formed between the upper end of the filter 16 and the upper wall 12 b of the housing 12. For this reason, the oil mist 19 having a large particle diameter is captured by the side surface of the baffle plate 17 and further accelerated through the first gap 18 and captured by the lower half portion 16a of the filter 16 due to inertial force. The oil mist 21 is then captured by the upper half 16b of the filter 16 and is captured by the upper half 16b when passing through the second gap 20.

  Therefore, according to the oil mist separator 11 of the first embodiment, the oil mist 19 having a large particle diameter and the oil mist 21 having a small particle diameter can be separated and captured, and the oil mist separation efficiency can be improved. it can. Furthermore, since the oil mist 19 having a large particle size is exclusively captured by the lower half 16a on the filter 16, clogging of the entire filter 16 can be suppressed, and the life of the filter 16 can be extended.

  (2) Since the first gap 18 is located at the lower end of the filter 16 and the second gap 20 is located at the upper end of the filter 16, the gas flow is raised along the filter 16. For this reason, the oil mist 19 having a large particle diameter and the oil mist 21 having a small particle diameter are captured by the filter 16 during the ascent, and the oil mist 19 having a large particle diameter falls on the bottom wall 12a during the ascent. Therefore, the separation efficiency of the oil mist 19 having a large particle diameter and the oil mist 21 having a small particle diameter can be further improved.

(3) In the unlikely event that the filter 16 is clogged, the gas flow will pass through the second gap 20, so that the gas flow will not be hindered, thus preventing an increase in the pressure in the crank chamber of the engine. It is possible to avoid an inconvenient situation of the engine.
(Second Embodiment)
Next, 2nd Embodiment of the oil mist separator 11 of this invention is described based on FIG.

  As shown in FIG. 3A, an auxiliary filter 23 is fixed to the upper wall 12b of the housing 12 in the second gap 20 so as to oppose the upper end surface of the filter 16, and therefore the second gap 20 is positioned at the upper and lower positions. Two filters 16 and 23 are arranged. The auxiliary filter 23 has the same configuration as the upper half 16b of the filter 16 and is configured to easily capture the oil mist 21 having a small particle diameter.

  In this case, since the oil mist 21 having a small particle diameter passing through the second gap 20 contacts both the lower filter 16 and the auxiliary filter 23 at the upper position, the oil mist 21 having a small particle diameter is in contact with the filter 16. Is effectively separated by the auxiliary filter 23.

  3B, a downstream baffle plate 24 is fixed downward from the upper wall 12b of the housing 12 on the downstream side of the filter 16. An auxiliary filter 23 is continuously disposed on the upper wall 12 b from the baffle plate 17 to the downstream baffle plate 24 and on the upstream side surface of the downstream baffle plate 24. A third gap 25 is formed between the downstream baffle plate 24 and the bottom wall 12 a of the housing 12. An upstream baffle plate 26 is fixed upward on the bottom wall 12a upstream of the baffle plate 17, and a fourth gap 27 is formed between the upstream baffle plate 26 and the upper wall 12b. . Accordingly, the blow-by gas flows from the fourth gap 27 to the first gap 18, and further flows to the third gap 25 in a meandering manner via the second gap 20.

  In this case, the oil mist 21 having a small particle size passing through the second gap 20 contacts the lower filter 16, the upper auxiliary filter 23, and the side auxiliary filter 23, so The half portion 16b and the auxiliary filter 23 are captured over a wide area.

(4) Therefore, according to the oil mist separator 11 of the second embodiment, the auxiliary filter 23 is provided on the side surface of the upper wall 12b of the housing 12 or the downstream baffle plate 24 in the second gap 20, and the small particle diameter is reduced. When the oil mist 21 passes through the second gap 20, the oil mist can be effectively captured by both the filter 16 and the auxiliary filter 23. Moreover, since the gas flow path is complicatedly meandered by the upstream baffle plate 26 and the downstream baffle plate 24, the oil mist 21 can be captured more effectively on the inner surface of the meandering flow path.
(Third embodiment)
Next, a third embodiment of the oil mist separator 11 of the present invention will be described with reference to FIG.

  As shown in FIG. 4A, an uneven portion 28 is provided on the upper wall 12 b of the housing 12 so as to face the upper end surface of the filter 16 in the second gap 20. The concavo-convex portion 28 is configured such that each convex portion 29 constituting the concavo-convex portion 28 is formed in a quadrangular cross section and arranged at substantially equal intervals, and a concave portion 30 is formed between the convex portions 29. The oil mist 21 is captured by the convex portion 29, and the small particle size oil mist 21 passing through the second gap 20 is guided to the filter 16 side by the concave and convex portion 28, and is easily attached to the upper portion of the filter 16. .

  In this case, the oil mist 21 having a small particle diameter passing through the second gap 20 strikes the convex portion 29 constituting the concave-convex portion 28 and is guided to the filter 16 side, and at the same time, the concave portion constituting the concave-convex portion 28. 30 enters and turns to be guided to the filter 16 side, and is attached to the upper part of the filter 16.

  4 (b), in addition to the configuration shown in FIG. 4 (a), a downstream baffle plate 24 is fixed downward from the upper wall 12b of the housing 12 to the downstream side of the filter 16, and the downstream side. An auxiliary filter 23 is provided on the upstream side surface of the side baffle plate 24. The most downstream convex portion 29 a constituting the auxiliary filter 23 and the concave and convex portion 28 is formed lower than the other convex portions 29. The auxiliary filter 23 has the same configuration as the upper half 16b of the filter 16 and is configured to easily capture the oil mist 21 having a small particle diameter.

  In the case of the configuration shown in FIG. 4B, the oil mist 21 having a small particle diameter passing through the second gap 20 is easily attached to the upper portion of the filter 16 by the uneven portion 28 and the second gap. After passing through 20, it is attached to the auxiliary filter 23.

(5) Therefore, according to the oil mist separator 11 of the third embodiment, in addition to the configuration of the first embodiment or the second embodiment, the uneven portion 28 is provided on the upper wall 12b of the housing 12 in the second gap 20. It has been. For this reason, the oil mist 21 having a small particle diameter in the blow-by gas passing through the second gap 20 can be easily brought into contact with the filter 16, and the oil mist separation efficiency can be improved.
(Fourth embodiment)
Next, a fourth embodiment of the oil mist separator 11 of the present invention will be described with reference to FIG.

  As shown in FIG. 5, the filter 16 has a substantially inverted trapezoidal cross section, the upper width (dimension in the gas flow direction) D is wider than the lower width d, and the upper portion separates the oil mist from the lower portion. The separation volume (separation area) is increased. For this reason, in the upper part of the filter 16, the capture efficiency of the oil mist 21 having a small particle diameter can be improved. An upstream baffle plate 26 is fixed upward on the bottom wall 12a upstream of the baffle plate 17, and a fourth gap 27 is formed between the upstream baffle plate 26 and the upper wall 12b. . Accordingly, the blow-by gas flows from the fourth gap 27 to the first gap 18 and further passes through the second gap 20 in a meandering manner.

  In this case, the blow-by gas that has passed through the first gap 18 via the fourth gap 27 is captured by the oil mist 19 having a large particle diameter colliding with the lower part of the filter 16. Next, although the gas flow rises, the filter 16 has a substantially inverted trapezoidal cross section, and the upstream side surface of the gas flow is inclined downward, so that the oil mist 19 with a large particle diameter and the oil with a small particle diameter Mist 21 is captured on this upstream side. Then, the oil mist 21 having a small particle diameter passing through the second gap 20 is guided to the upper side of the filter 16 along the filter 16, and is captured by the upper part of the filter 16 when passing through the second gap 20. In addition, as shown by a two-dot chain line in FIG.

  (6) Therefore, according to the oil mist separator 11 of the fourth embodiment, the upper part of the filter 16 is formed wider than the lower part and the separation volume is large. The capture efficiency can be increased.

  (7) Moreover, since the upstream side surface of the filter 16 is inclined downward, the oil mist 19 having a large particle diameter and the oil mist 21 having a small particle diameter can be effectively captured by the side surface.

It should be noted that the above embodiment can be modified as follows.
As shown in FIG. 6A, in the fourth embodiment, the auxiliary filter 23 may be disposed on the upper wall 12b of the housing 12 so as to face the upper end surface of the filter 16 as in the second embodiment. .

  As shown in FIG. 6B, in the fourth embodiment, an uneven portion 28 may be provided on the upper wall 12b of the housing 12 so as to face the upper end surface of the filter 16 as in the third embodiment.

  As shown in FIG. 7, the filter 16 can also be formed in a substantially trapezoidal cross section so that the upper part is narrower than the lower part. The filter 16 is configured such that the upper part is closer to the upper part than the lower part. Furthermore, an auxiliary filter 23 can be provided on the upstream side surface of the downstream baffle plate 24. The upstream side surface of the auxiliary filter 23 is an inclined surface 23 a parallel to the downstream side surface of the filter 16. The inclined surface 23 a can improve the oil mist capturing performance of the auxiliary filter 23.

  As shown in FIG. 8, it is also possible to form the filter 16 in two upper and lower stages by the partition wall 31, to form the lower filter 16c with thick fibers, and to form the upper filter 16d with thin fibers. Alternatively, it is possible to form the lower filter 16c so that the fibers become coarse and form the upper filter 16d so that the fibers are dense. In this case, if the edge 31a on the upstream side of the gas flow of the partition wall 31 is protruded toward the upstream side, the gas flow stays below the edge 31a. For this reason, oil mist can be effectively captured in the lower filter 16c.

  As shown in FIG. 9, on the downstream side of the baffle plate 17, two filters 16A and 16B having the same configuration as the lower half 16a of the filter 16 are directed upward from the bottom wall 12a on the upstream side and spaced apart on the downstream side. It is fixed downward from the upper wall 12b. An end plate 32 is attached to the tip of each filter 16A, 16B so that the end edge 32a protrudes upstream. Two filters 16C and 16D having the same configuration as the upper half portion 16b of the filter 16 are spaced upward from the bottom wall 12a on the upstream side, and spaced apart on the downstream side. And fixed downward from the upper wall 12b. An end plate 33 is attached to the front end of each filter 16C, 16D so that its end edge 33a protrudes upstream.

  The gas flow meanders through the first gap 18, the second gap 20, the fifth gap 34, the sixth gap 35, and the seventh gap 36, and the oil mist 19 having a large particle diameter mainly passes through the filters 16A and 16B. The oil mist 21 having a small particle diameter is captured mainly by the filters 16C and 16D.

  As shown in FIG. 10, in the embodiment shown in FIG. 8, the partition wall 31 is omitted, and the upper filter 16d can be formed to have a larger volume than the lower filter 16c. In this case, the upper filter 16d can improve the trapping efficiency of the oil mist 21 having a small particle diameter, and the upstream end 16e of the upper filter 16d protrudes more upstream than the upstream end of the lower filter 16c. Therefore, the gas flow stays below the protrusion 16e, and the oil mist can be captured effectively.

  The surface of the auxiliary filter 23 facing the filter 16 may be formed in a concavo-convex shape so that the trapping efficiency of the oil mist 21 having a small particle diameter in the filter 16 and the auxiliary filter 23 can be increased.

  -In each said embodiment, it is good also as a structure which reversed the filter 16 and the baffle plate 17 upside down. That is, the first gap 18 is formed on the upper side and the second gap 20 is formed on the lower side.

  In each of the above embodiments, the lower half 16a and the upper half 16b of the filter 16 are configured separately, but the lower half 16a is not formed so that the boundary between the lower half 16a and the upper half 16b is not formed. A region where these fibers are mixed may be provided between the upper half portion 16b and the upper half portion 16b.

  DESCRIPTION OF SYMBOLS 11 ... Oil mist separator, 12 ... Housing, 12a ... Bottom wall, 12b ... Upper wall, 13 ... Inlet, 14 ... Outlet, 15 ... Blow-by gas channel, 16, 16A, 16B, 16C, 16D ... Filter, 17 DESCRIPTION OF SYMBOLS ... Baffle plate, 18 ... 1st gap | interval, 19 ... Large particle diameter oil mist, 20 ... 2nd gap | interval, 21 ... Small particle diameter oil mist, 22 ... Oil discharge hole, 23 ... Auxiliary filter, 28 ... Uneven part.

Claims (5)

A housing for separating oil mist contained in the oil mist-containing gas is provided with an inlet and an outlet for the oil mist-containing gas to form a flow path through which the oil mist-containing gas flows from the inlet to the outlet. This is an oil mist separator in which a filter for separating oil mist contained in a mist-containing gas is disposed across the flow path, and a discharge hole for discharging oil separated by the filter is provided in the bottom wall of the housing. And
A baffle plate is provided on the inner wall surface of the housing with an interval on the upstream side of the filter, and a first gap is formed between the other inner wall surface facing the inner wall surface and the baffle plate, and the baffle plate Forming a second gap between the filter end on the proximal side and the inner wall surface of the housing;
The second gap side end of the filter is formed wider than the base end side in the gas flow direction, and the second gap side of the filter is formed with a higher density than the base end side. Oil mist separator. The baffle plate is formed downward from the upper wall of the housing to form the first gap between the lower end of the housing and the bottom wall of the housing, and the filter is provided on the bottom wall of the housing. The oil mist separator according to claim 1, wherein the second gap is formed between the upper wall and the upper wall. The oil mist separator according to claim 1 or 2, wherein the second gap is formed narrower than the first gap. The oil mist separator according to any one of claims 1 to 3, wherein an auxiliary filter is provided on the inner wall surface of the housing in the second gap so as to face an end face of the filter. The oil mist separator according to any one of claims 1 to 4, wherein an uneven portion is provided on the inner wall surface of the housing in the second gap so as to face the end face of the filter .

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