JPH0718433B2 - Fan and oil mist removing device using fan - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a centrifugal fan provided with a function for generating an axial flow.

[0002]

2. Description of the Related Art The applicant of the present invention has already applied for Japanese Patent Application No. 2-104315 as an oil mist removing device. This Japanese Patent Application No. 2-104315 is disclosed in FIGS.
As shown in FIG. 4, a fan 4 for forcibly flowing gas containing oil mist from the suction portion 2 at one end of the oil mist removal air passage 1 to an exhaust portion (not shown) at the other end, and an oil mist A thin film filter 5 is arranged in the removal air passage 1 so as to partition the oil mist removal air passage 1 into the windward side and the leeward side, and the gas is collided by being placed on the leeward side of the thin film filter 5. Is provided with an oil mist trapping portion 7 for trapping the oil mist by collision while changing the gas flow direction.

Then, the fan 4 is rotated to suck the gas containing the oil mist into the suction portion 2 of the oil mist removing air passage 1.
When the fan 4 forcibly flows from the above to the exhaust side, the thin film is provided in the middle of the oil mist removing air passage 1 so as to be divided into the windward side and the leeward side. When a gas containing oil mist passes through the particulate filter 5, it is once captured and thin film filter 5
Is a clogged state (that is, a saturated state), but even if the clogged state is a thin film, the oil mist trapped between the fibers of the thin film filter 5 is pressed by the wind pressure to form a thin film. It moves to the rear side (leeward side) of the filter 5, and the oil mist aggregates at the rear side of the thin film filter 5 to form an oil mist with a relatively large diameter, which rides on the forced flow of gas. Flown to the leeward side of the thin film filter 5, but the aggregate of the oil mist having a relatively large diameter that has flowed away from the thin film filter 5 to the lee side of the thin film filter 5 traps the oil mist. It collides with the portion 7 to change the flow direction and collides with the portion 7 to be separated from the gas and captured. Then, by designing the capacity of the fan 4 so that the required air volume is reached when the thin membrane filter 5 becomes clogged and becomes saturated, the thin membrane filter 5 becomes saturated immediately because it is thin. After that, a part of the oil mist trapped in a saturated state by the thin film filter 5 by the air volume set by the fan 4 is pushed to the back side, moves, aggregates and flows to the leeward side, and a new thin film is formed. The oil mist is trapped by the filter 5 and is in a saturated state. Therefore, after the saturated state, the air volume does not decrease, and the oil mist capturing efficiency can be the same. .

As shown in FIGS. 18 and 19, the fan 4 used in the conventional oil mist removing device shown in FIGS. 18 and 19 has a central portion in front of the disk portion 13 fixed to the motor shaft 10. The ring-shaped plate portion 14 serving as the opening 15 is arranged to face each other, and a plurality of blade portions 16 bent in a dogleg shape in a front view are provided between the ring-shaped plate portion 14 and the disc portion 13 so as to extend therethrough. The fan 4 of the centrifugal type was used.

[0005]

However, in the above-mentioned conventional example, as shown in FIG. 20, the outer end portion of the blade portion 16 bent in the shape of a fan 4 is located outside the disk portion 13. In addition, the fan 4 has both the inner portion and the outer portion of the bent portion perpendicular to the rotation direction, which coincide with the end portion. In the fan 4 having such a configuration, the ring-shaped plate portion 1 of the fan 4 is formed.
The gas containing the oil mist flowing in from the central opening 15 of 4 hits the outside of the bent portion of the blade 16 to separate the oil mist and the gas, but the oil mist and the gas are separated by the centrifugal force of the fan. It flows in the outer peripheral direction of the fan 4, and the oil mist and the gas are not sufficiently separated, that is, the oil mist and the gas are blown in the outer peripheral direction of the fan 4 by the centrifugal force of the fan 4, and the casing 9
The oil mist trap 7 collides with the oil mist trap 7 on the inner wall of the oil mist, and the oil mist aggregates are trapped by the oil mist trap 7, but when the gas also hits the same direction and flows to the membrane filter 5 side, it is temporarily collided. The separated agglomerates of the oil mist may be carried by this gas, and in the end, a large amount of the oil mist flows together with the gas, and since this is separated, conventionally, as shown in FIG. 18 and FIG. There is a problem that the membrane filter 5 is required in the middle of the air passage. Further, since the conventional fan 4 is of a centrifugal type, it hits the inner wall of the casing 9 and changes its direction. Therefore, the air volume could not be efficiently increased.

That is, in the conventional fan 4, the casing 9
There is a problem that the oil mist trapping portion 7 on the inner wall of the oil mist has a poor oil mist trapping efficiency, and since the membranous filter 5 is provided in the middle of the oil mist removing air passage, the treated air volume is reduced, and the centrifugal type fan is also used. Since it is 4, there is a problem that the air volume cannot be increased efficiently also in this respect.

Therefore, in the process of reaching the present invention, FIGS.
As shown in FIG. 2, a ring-shaped plate portion 14 having an opening 15 at the center is disposed in front of the disk portion 13 fixed to the motor shaft 10, and the ring-shaped plate portion 14 and the disk portion 13 are separated from each other. A plurality of vane portions 16 that are bent in a V shape in a front view are provided between them, and an outer portion 16b of the vane portion 16 that is bent in a V shape is located outside the outer peripheral end of the disc portion 13. The outer portion 16b of the blade portion 16 that is bent in a dogleg shape and is located inside the bent portion 16a
A fan device having a configuration in which the front end edge 16d and the rear end edge 16e of the outer portion 16b are twisted with respect to c in relation to the rotation direction so as to be displaced from the bent portion 16a is considered. This is like combining an axial fan with the outer circumference of a centrifugal fan, and when the fan 4 rotates, the ring-shaped plate portion 14
The gas containing the oil mist is sucked in from the central opening 15 and flows along the blade portion 16. At this time, the blade portion 16
Since the bent portion 16a is provided in the
Baffle effect changes the flow direction of the gas containing the oil mist and collides with the blade portion 16 to separate the aggregate of the oil mist from the gas, and the bent portion 16a of the blade portion 16 bent in a dogleg shape. Outer part 16b
Of the blade portion 16 bent outward in a dogleg shape and the outer portion 16b of the blade portion 16 bent in a dogleg shape is twisted with respect to the inner portion 16c of the bent portion 16a. Therefore, since the front end edge 16d and the rear end edge 16e of the outer side portion 16b are displaced from the bent portion 16a with respect to the rotation direction, the agglomerates of oil mist heavier than gas are centrifugal force of the fan 4. The gas separated from the oil mist aggregates is guided by the outer portion 16b of the blade portion 16 which is twisted and inclined and is slanted rearward as shown by the arrow in FIG. This is because the separated oil mist and gas are changed in the main outflow direction when exiting from the fan 4, and the oil mist can be efficiently captured. Therefore, in the fan device having the above-described structure, the outer portion 16 of the blade portion 16 that is bent like a dogleg is more than the bent portion 16a.
The direction of gas flow is determined by the shape of b, and as shown in FIG.
Distance L from the outer end of the front edge 16d of b to the motor shaft 10
_If the distance L ₂ from the outer end of the rear end edge 16e of the outer portion 16b to the motor shaft 10 is longer than that of the bent portion 16 as shown in FIG.
The angle α at 2 increases, and the gas flows obliquely outward and rearward. However, when the angle α becomes large in this way, the gas collides with the latter half of the inner peripheral wall of the casing 9 as shown by the arrow in FIG. 22, and the guide vane body 12 is directly passed through the gap between the rear plate 17 and the front plate 18. Since it flows inside, there is an advantage that the resistance when flowing in the guide vane body 12 is small and the motor can be downsized, but on the other hand, almost no oil mist contained in the gas is removed when passing through the guide vane body 12. It turned out to be a problem.

The present invention has been made in view of the above problems of the prior art, and an object of the present invention is to provide an oil mist and a gas when the gas containing the oil mist passes through the blades of the fan. To separate the oil mist and change the main outflow direction of the separated oil mist and gas from the fan to efficiently capture the oil mist, and further to guide the separated gas by the guide blades and send it out as much as possible. , A fan and a fan capable of efficiently separating the oil mist in the gas in the guide blade body while flowing in a zigzag collision in the guide blade body when passing through the guide blade body as a flow approaching parallel to the motor shaft. It is to provide an oil mist removing device used.

[0009]

In order to solve the problems of the conventional example and to achieve the object of the present invention, a fan of the present invention has a central portion in front of a disk portion 13 fixed to a motor shaft 10. The ring-shaped plate portions 14 having the openings 15 are arranged so as to face each other,
Between the ring-shaped plate portion 14 and the disc portion 13, a plurality of blade portions 16 that are bent in a V shape are radially installed between the ring-shaped plate portion 14 and the circular plate portion 13 and are outside the bent portion 16a of the blade portion 16 that is bent in a V shape. Part 6
b is projected outward from the outer peripheral end of the disc portion 13 and the outer portion 16b of the blade portion 16 bent in the V-shape is twisted with respect to the inner portion 16c of the bent portion 16a. Therefore, the front end edge 16d and the rear end edge 16e of the outer portion 16b are displaced from the bent portion 16a with respect to the rotation direction so that the front end edge 16d and the rear end edge 16e of the outer portion 16b are offset from the outer end of the front end edge 16d of the outer portion 16b. It is characterized in that the distance to 10 is equal to or greater than the distance from the outer end of the rear end edge 16e of the outer portion 16b to the rotating shaft 10 with respect to the bent portion 16a.

Further, the oil mist removing device using the fan of the present invention has a large-diameter rear plate 1 having a hole 19 in the center thereof.
A front plate 18 having a diameter smaller than that of the rear plate is arranged in front of 7, and a plurality of guide blades 20 are provided between the front plate 18 and the rear plate 17 to form a guide blade body 12, and inside the casing 9. The guide vane body 12 is arranged after the fan 4 in the casing 9 while the fan 4 according to claim 1 is arranged, and the portion of the fan 4 projecting outward beyond the bent portion 16a is guided by the guide vane body 1.
2 and the front surface of the outer peripheral portion of the rear plate 17 are opposed to each other, and the outer peripheral surfaces of the fan 4 and the guide blade body 12 are surrounded by the inner peripheral wall 24 of the casing 9, and the rear plate 17 of the guide blade body 12 is connected to the blade portion 1 of the fan 4.
The rear end edge 16e of the portion 16b outside the bent portion 16a of 6
It is characterized by being opposed to.

[0011]

When the fan 4 rotates, the gas containing the oil mist is sucked from the central opening 15 of the ring-shaped plate portion 14 and flows along the blade portion 16. At this time, the blade portion 16
Since the bent portion 16a is provided in the
Due to the baffle effect, the flow direction of the gas containing the oil mist is changed and collides with the blade portion 16 to separate the aggregate of the oil mist from the gas. The outer portion 16 of the blade 16 that is bent in a dogleg shape is more than the bent portion 16a.
b of the blade portion 16 bent outwardly from the outer peripheral end of the disc portion 13 and the outer portion 16b of the blade portion 16 bent from the bent portion 16a to the inner portion 16c of the bent portion 16a.
Since the front end edge 16d and the rear end edge 16e of the outer portion 16b are twisted with respect to the rotational direction with respect to the rotation direction, the front end edge 16d and the rear end edge 16e are inclined so that aggregates of oil mist that are heavier than gas are The centrifugal force of the fan 4 causes the gas to be blown out in the outer peripheral direction of the fan 4, but the gas from which the oil mist aggregates have been separated is twisted and inclined to the outer portion 16b of the blade portion 16.
And is sent obliquely rearward, whereby the separated outflow direction of the oil mist and gas from the fan 4 can be changed to efficiently capture the oil mist. Is. At this time, the distance from the outer end of the front end edge 16d of the outer portion 16b beyond the bent portion 16a to the motor shaft 10 is equal to or more than the distance from the outer end of the rear end edge 16e of the outer portion 16b beyond the bent portion 16a to the rotary shaft 10. Thus, when separating the oil mist and the gas, it becomes possible to make the flowing direction of the gas as parallel to the motor shaft 10 as possible, and to make the gas flow parallel to the parallel direction. Can be optimally adapted to.

A front plate 18 having a diameter smaller than that of the rear plate is arranged in front of a large-diameter rear plate 17 having a hole 19 in the center thereof, and a guide blade portion 20 is provided between the front plate 18 and the rear plate 17. The guide vane body 12 by constructing a plurality of
The guide blade body 12 is arranged inside the casing 9 after the fan 4 in the casing 9 and the fan 4 according to claim 1 is arranged. The front surfaces of the outer peripheral portions of the plates 17 are opposed to each other, and the inner peripheral wall 24 of the casing 9 surrounds the outer peripheries of the fan 4 and the guide blade body 12, and the rear plate 17 of the guide blade body 12 is more than the bent portion 16a of the blade portion 16 of the fan 4. By facing the rear edge 16e of the outer portion 16b, the gas discharged from the fan 4 flows so as to be as parallel to the motor shaft 10 as possible and hits the rear plate 17 of the guide vane 12 to reach the guide vane 12 When flowing into the guide vane body 12, it repeatedly flows in a zigzag manner while repeatedly colliding, and when colliding with the rear plate 17, the front plate 18, and the guide vane portion 20 in the guide vane body 12, the oil contained in the gas Mist is intended to be further agglomerated.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below in detail with reference to the embodiments shown in the accompanying drawings. The fan 4 of the present invention has a disc portion 13 fixed to a motor shaft 10 as shown in FIGS.
3, a ring-shaped plate portion 14 having an opening 15 at the central portion and a diameter smaller than that of the disk portion 13 is arranged in opposition to each other, and a space between the ring-shaped plate portion 14 and the disk portion 13 is seen in a front view. A plurality of blade portions 16 that are bent in a radial shape are radially installed. Here, the blade portion 16 bent in a dogleg shape is the bent portion 1
The outer portion 16b of the blade portion 16 is protruded outwardly from the outer peripheral end of the disc portion 13, and the outer portion 16b of the blade portion 16 is bent in a dogleg shape. Is also twisted with respect to the inner part 16c,
The front end edge 16d and the rear end edge 16e of the outer portion 16b are inclined with respect to the rotation direction so as to deviate from the bent portion 16a. Further, the distance from the outer end of the front end edge 16d of the outer portion 16b to the motor shaft 10 with respect to the bent portion 16a (see FIG. 2,
(L ₁ in FIG. 17) is more than the distance (L ₂ in FIGS. 2 and 17) from the outer end of the rear edge 16e of the outer portion 16b to the motor shaft 10 than the bent portion 16a (L _{1 in} FIG. 2).
And L ₂ are the same). Here, although the bent portion 16 of the blade portion 16 is a straight line and the cross section of the outer portion 16b is straighter than the bent portion 16, the bent portion 16 has an arc shape as shown in FIGS. The cross section of the outer portion 16b may be arcuate.

The fan 4 having the above structure is used for removing oil mist, for example. For example, it can be used as a fan of an oil mist removing device as shown in FIGS. 7 and 8 show the oil mist removing device 8. An oil mist from the suction portion 2 to the exhaust portion 3 is provided in the casing 9 by providing the suction portion 2 at one end of the casing 9 of the outer shell of the oil mist removing device 8 and the exhaust portion 3 at the other end of the casing 9. The removal air passage 1 is configured. A motor shaft 10 which is rotated by a motor 11 is inserted into the casing 9 so that the motor shaft 1
A plurality of fans 4 are fixed to 0, and guide vanes 12 are provided between the fans 4. Here, as the fan 4 used in the oil mist removing device 8, the fan 4 according to the present invention shown in FIGS. 1 and 2 described above is used.

The guide vane body 12 has a large-diameter rear plate 17 having a hole 19 in the central portion and a front plate 18 having a smaller diameter than the large-diameter rear plate 17 arranged opposite to each other, and the guide vane portion is provided between the front plate 18 and the rear plate 17. 20 is installed and constructed. As shown in FIG. 9, the guide vane portion 20 is bent in a dogleg shape in a front view similarly to the vane portion 16 of the fan 4, but is not necessarily limited to the dogleg portion bent as described above. . Here, the casing 9 is configured by connecting a plurality of divided casing bodies 21,
The flange portions 22 of the divided casing bodies 21 are joined together by bolts and nuts. In this case, the guide vane body 12 is mounted in the casing 9 at the same time when the divided casing bodies 21 are connected by sandwiching the outer peripheral end portion of the rear plate 17 of the guide vane body 12 between the flange portions 22. By doing so, the rear plate 17 of the guide blade body 12 is located outside the bent portion 16a of the blade portion 16 of the fan 4 as shown in FIG.
It faces the rear edge 16e of b. Also, the rear plate 1
The hole 19 at the center of 7 faces the opening 15 of the ring-shaped plate 14 of the fan 4 that is adjacent to the rear. Then, by sandwiching the outer peripheral end of the rear plate 17 of the guide blade 12 between the flanges 22 in this manner, the gas flowing rearward from the outer periphery of the fan 4 is transferred to the guide blade 20 of the guide blade 12. The opening 1 of the next fan 4 that passes through the guide vane portion 20 through the gap between the outer ends and exits from the hole 19 and is adjacent to the rear side
It is designed to flow into 5.

The inner peripheral wall 24 of the casing 9 serves as an oil mist trapping portion 7 against which agglomerates of oil mist blown by the centrifugal force of the fan 4 in the outer peripheral direction of the fan 4 collide. As shown in FIG. 10, a spiral oil discharge groove 25 is formed on the inner surface of the inner peripheral wall 24 of the casing 9 serving as the oil mist trapping portion 7, and the spiral oil discharge groove 2 is formed.
The end of 5 communicates with an annular groove 25a provided over the entire inner circumference of the casing 9, and a discharge hole 26 is provided at the lowermost end of the annular groove 25a so as to penetrate the casing 9. That is, the oil mist captured by the oil mist capturing portion 7 is transmitted to the outside through the spiral oil discharge groove 25 and the discharge hole 26 via the annular groove 25a.

In the embodiment shown in FIG. 3 as an overall view, the oil mist removing device 8 having the above construction is internally provided in a box 27 as shown in FIGS. 4, 5 and 6. The box 27 is attached to the base 40, and the oil mist removing device 8 is fixed to the base 40. In this case, the motor 11 is also fixed to the base 40. And, the plate portion 4 is provided on the base 40.
1 is provided, and the oil from the discharge hole 26 can
It is designed to flow to 1. An oil drain hole 42 is provided in the plate portion 41.
Is provided. The box 27 is divided into a front chamber 28, an oil mist removing device storage chamber 29, and a rear chamber 30, and the front chamber 28 is provided with a suction port 31. A detachable window portion 32 is provided on a side portion of the box body 27, and a suction portion 2 of the oil mist removing device 8 is opened at a position facing the window portion 32 of the front chamber 28. A supporting cylinder 33 that communicates with the front chamber 28 is projected. And the window part 3
2 is removed, a cylindrical thick filter 34 is inserted into the front chamber 28 from the side hole of the box 27, and the rear end edge of the cylindrical thick filter 34 is fitted into the support cylinder 33. It is attached. Therefore, the gas containing the oil mist sucked from the suction port 31 enters the front chamber 28,
It passes through the thick filter 34 and flows into the suction portion 2 of the oil mist removing device 8. The exhaust part 3 of the oil mist removing device 8 is provided at the upper part of the rear part of the casing 9 and communicates with the upper part of the rear chamber 30.
As shown in FIG. 11, the rear chamber 30 is divided into two chambers 30a and 30b by a partition 35, and the lower portion of the partition 35 is opened to connect the two chambers 30a and 30b.
The exhaust port 36 of the box 27 is formed in the upper part of the room 30b where the exhaust unit 3 is not provided. That is, the gas flowing out from the exhaust unit 3 into the chamber 30a hits the cushioning material 44 such as the non-woven fabric provided in the chamber 30a and flows downward, flows through the opening below the partition 35, and rises in the chamber 30b to rise from the exhaust port 36. It is exhausted, but in this case the gas is U
The oil mist is prevented from re-scattering because it is meandered in a circular shape, and the sound is silenced by passing through the rear chamber 30. Further, the oil that hits the cushioning material 44 and is prevented from re-scattering is discharged from the outlet 45 to the outside.

Thus, the oil mist removing device 8 using the fan 4 of the present invention having the above-mentioned structure captures the oil mist generated from the lathe or grinder that is the oil mist generating source. In order to capture the above, when the fan 4 is operated, the gas containing the oil mist is sucked into the front chamber 28 through the suction port 31 through the hood (not shown) and the duct (not shown), and the thicker The filter 34 traps dust such as cutting chips or grinding powder contained in the gas. In this case, part of the oil mist is captured by the thick filter 34. The gas containing the oil mist that has passed through the thick filter 34 is sucked into the suction portion 2 of the oil mist removing device 8.
Through the oil mist removing air passage 1, the oil mist is separated and captured when passing through the oil mist removing air passage 1, gas flows from the exhaust portion 3 to the rear chamber 30, and the exhaust port 36 passes through the rear chamber 30. It is exhausted to the outside. In FIGS. 5 and 6, the flow of gas is indicated by arrows. As shown in FIGS. 7 and 8, the last stage fan uses the same centrifugal type fan 4'as the conventional one.

Here, the oil mist is removed by the oil mist removing device 8 as follows. That is, when the fan 4 is rotated, the gas flows through the opening 15 of the first-stage fan 4 and passes through the gap between the gas foil-shaped blade portions 16 to form a dogleg shape. The oil mist collides with the blades 16 to aggregate the oil mist, and the aggregated substance with the oil mist is aggregated to a large diameter by the centrifugal force due to the rotational force of the fan 4 to increase the mass, and the first-stage divided casing body 21 The oil mist aggregates are separated and captured in the first stage by colliding with the front half of the inner peripheral wall 24 of the. On the other hand, the bent portion 16b of the vane portion 16 bent in a dogleg shape is formed so that the outer portion 16b of the vane portion 16 bent in a dogleg shape is projected outward beyond the outer peripheral end of the disc portion 13. The outer portion 16b of the outer portion 16a is twisted with respect to the inner portion 16c of the bent portion 16a so that the front end edge 16d and the rear edge 16e of the outer portion 16b of the outer portion 16b of the bent portion 16a are displaced relative to the rotational direction. Therefore, as described above, the aggregate of oil mist that is heavier than gas is blown by the centrifugal force of the fan 4 in the outer peripheral direction of the fan 4 (the direction of the arrow A in FIGS. 7 and 12) and the divided casing body 21 is discharged. Although the gas is separated by colliding with the oil mist trapping portion 7 which is the inner peripheral wall 24, the gas from which the oil mist aggregates are separated is guided backward by the outer portion 16b of the blade portion 16 which is twisted and inclined (FIG. 7). , Of FIG. Flows in Shirushiro direction), it flows into the opening 15 of the next fan 4 passes between guide vanes 20 of the guide vanes 12. The gas flowing into the opening 15 of the next fan 4 contains part of the oil mist without being separated, but when passing through the second stage fan 4, the gas of the first fan 4 Similarly to the operation, the centrifugal force of the fan 4 causes the oil mist aggregates to collide with the inner peripheral wall 24 of the second-stage divided casing body 21 to separate and capture the oil mist aggregates in the second stage. On the other hand, the gas is guided rearward by the inclined surface of the outer portion 16b of the bent portion 16a of the fan 4 and passes between the guide blade portions 20 of the guide blade body 12 to reach the opening 15 of the next fan 4. Flowing. Similarly, the gas containing the oil mist is successively flowed in the order of the fan 4, the guide blade body 12, the fan 4, the guide blade body 12, and the oil mist in the gas is separated and captured from the gas. is there. In this way, the oil mist in the gas is removed by passing through the oil mist removing air passage 1 of the oil mist removing device 8 while repeating the same one after another. The oil mist trapped in the oil mist trapping portion 7 which is the inner peripheral wall 24 of the casing 9 travels through the spiral oil discharge groove 25 and flows toward the discharge hole 26 side by wind pressure, and the dish portion provided on the base 40 through the discharge hole 26. It is discharged to the 41 side.

In the present invention, the outer portion 16b of the blade portion 16 bent in a dogleg shape is projected outward from the outer peripheral end of the disk portion 13 and is formed in the dogleg shape. Of the bent blade portion 16, the outer portion 16b of the bent portion 16a is twisted with respect to the inner portion 16c of the bent portion 16a so that the front end edge 16d of the outer portion 16b of the bent portion 16a and the rear portion of the outer portion 16b of the bent portion 16a are twisted. Since the end edge 16e is inclined so as to be displaced from the end edge 16e, when the fan 4 goes out, the aggregate of the oil mist that is heavier than the gas is blown toward the outer peripheral direction of the fan 4 by the centrifugal force of the fan 4, The gas from which the mist aggregates have been separated is guided by the outer portion 16b of the blade portion 16 which is twisted and inclined and is sent obliquely rearward. As a result, the separated oil mist and the gas are separated from each other. The main outflow direction when exiting from No. 4 can be changed to efficiently capture the oil mist. As a result, a film filter is provided in the oil mist removing air passage 1 as in the conventional case, and the oil mist is condensed and expanded here. It is no longer necessary and is smoothly sent to the fan 4 in the next stage, and the amount of treated air is greatly improved.

Further, in the present invention, the distance from the outer end of the front end edge 16d of the outer side portion 16b to the motor shaft 10 is greater than the outer end of the rear end edge 16e of the outer side portion 16b beyond the bent portion 16a. Since the distance is greater than the distance to the rotary shaft 10, the angle α shown in FIG. 12 becomes smaller, and as a result, the gas flows as parallel to the motor shaft 10 as possible and the rear plate 17 of the guide vane body 12 is When it hits the plate 17 and flows in the guide vane body 12 while repeatedly colliding in a zigzag manner in the guide vane body 12, it flows and collides with the rear plate 17, the front plate 18, and the guide vane part 20 in the guide vane body 12. The oil mist contained in the gas is further aggregated. The particles of the oil mist aggregated in the guide vane body 12 gradually become large particles by repeating collision, and these particles ride on the flow of the gas flowing through the guide vane body 12 from the opening 15 of the fan 4 in the next stage. Four
When it enters the inside, it is blown off by the centrifugal force to the inner peripheral wall 24 of the next stage by the action of the fan 4 and is collected. By doing so, the efficiency of separating and removing the oil mist remarkably Will be improved.

In the above embodiment, the fan 4 is arranged in multiple stages, but the fan 4 may be arranged in one stage in the middle of the oil mist removing air passage 1. Further, the oil mist removing air passage 1 is not limited to the one in the above-described embodiment, and a gas containing the oil mist is made to flow by the fan 4 to separate the oil mist and the gas on the way to remove the oil mist. Of course, other various forms may be used. Further, even if it is used as a blower fan, the resistance of the ventilation passage is reduced, and a large air volume can be obtained with a small housing.

Further, in the embodiment shown in FIGS. 1, 2 and 13, the bent portion 16 of the blade portion 16 bent in a dogleg shape in front view.
When the inner portion 16c is bent in an arc shape from the side closer to the motor shaft 10 to the side closer to the bent portion 16a than the a, the air volume can be increased, but it is not necessarily limited thereto. In addition, the inner portion 16c may have a flat plate shape. Such flat plate shape facilitates manufacture and assembly.

Further, the cross-sectional shape of the vane portion 16 in the front-rear direction may be bent in a substantially V shape, a substantially U shape, or a substantially arc shape as shown in FIG. In this case, the air volume can be increased. Furthermore, in FIG.
Front edge 16 of the outer portion 16b of the bent portion 16a
The distance from the outer end of d to the motor shaft 10 is set from the outer end of the rear end edge 16e of the outer portion 16b beyond the bent portion 16a to the rotary shaft 1
There is an example that is longer than the distance to 0,
By doing so, the gas can be brought closer to be parallel to the motor shaft 10.

[0025]

As described above, according to the present invention, the ring-shaped plate portions having an opening at the central portion are arranged in front of the disk portion fixed to the motor shaft so as to face each other. A plurality of blades that are bent in a V shape in front view are installed between the disk part and
The outer side portion of the blade portion bent in a dogleg shape is protruded outward from the outer peripheral end of the disk portion, and the outer portion of the blade portion bent in a dogleg shape is bent from the bent portion. Is also twisted with respect to the inner part and tilted so that the front edge and the rear edge of the outer part deviate from the bent part with respect to the rotating direction, so when the fan rotates, the center of the ring-shaped plate part The gas containing oil mist is sucked in through the opening of the and flows along the blade, but at this time, the flow direction of the gas containing oil mist is changed by the baffle effect of the V-shaped blade. Not only the oil mist aggregates are separated from the gas by colliding with the gas, but also the outer side portion of the blade portion bent in a dogleg shape is projected outward from the outer peripheral end of the disk portion and Out of the bent part of the V-shaped bent part The part is twisted with respect to the inner side of the bent part and inclined so that the front end edge and the rear end edge of the outer side part with respect to the rotational direction are displaced with respect to the rotation direction, so that the oil mist that is heavier than gas is used. The agglomerates are blown toward the outer circumference of the fan by the centrifugal force of the fan, but the gas from which the agglomerates of the oil mist has been separated is twisted and guided to the outer side of the slanted blades and sent backward. Therefore, by this, the main outflow direction when the separated oil mist and the gas exit from the fan is changed, and the oil mist can be efficiently separated and captured. Moreover, in the present invention, the distance from the outer end of the front edge of the portion outside the bent portion to the motor shaft is equal to or greater than the distance from the outer end of the rear edge of the portion outside the bent portion to the rotating shaft. Therefore, when separating oil mist and gas, it is possible to make the direction of gas flow as parallel as possible to the motor shaft, and it is ideal for those that flow gas substantially parallel to the motor shaft. Can be adapted to.

Further, a front plate having a smaller diameter than the rear plate is arranged in front of a large-diameter rear plate having a hole in the center, and a plurality of guide vanes are provided between the front plate and the rear plate. The guide vane body is formed, the fan according to claim 1 is arranged in the casing, the guide vane body is arranged after the fan in the casing, and the portion protruding outward from the bent portion of the fan is formed in the guide vane body. The front surface of the outer peripheral portion of the rear plate is opposed, and the inner peripheral wall of the casing surrounds the outer periphery of the fan and the guide blade body, and the rear plate of the guide blade body is opposed to the rear end edge of the portion outside the bent portion of the guide blade portion of the fan. Since it is made possible, the gas discharged from the fan can be made to flow as parallel as possible to the motor shaft and can collide with the rear plate of the rear plate of the guide blade body. Smell inside guide vanes when flowing into the body Flow while repeatedly colliding with the zigzag plate after the guide vane body, the front plate, oil mist contained in the gas when it collides with the guide vane section is further agglomerated,
This improves the aggregation and collection efficiency of oil mist.

[Brief description of drawings]

FIG. 1 is a perspective view of a fan of the present invention.

FIG. 2 is a front view of the above.

FIG. 3 is an overall perspective view of an oil mist removing device using the above fan.

FIG. 4 is a partially cutaway perspective view of the above.

FIG. 5 is a side sectional view of the above.

FIG. 6 is a plan sectional view of the above.

FIG. 7 is an enlarged cross-sectional view of the oil mist removing device portion of the above.

FIG. 8 is an exploded perspective view of the above.

FIG. 9 is a front sectional view of the guide vane body of the above.

FIG. 10 is a schematic perspective view for explaining an oil discharge groove of the above divided casing body.

11A and 11B are a plan view and a front view showing a rear chamber portion.

FIG. 12 is an explanatory view of the operation of the present invention.

FIG. 13 is a perspective view of another embodiment of the fan of the present invention.

14 is a sectional view taken along line XX of FIG.

FIG. 15 is a perspective view of still another embodiment of the present invention.

FIG. 16 is a perspective view of still another embodiment of the present invention.

FIG. 17 shows still another embodiment of the present invention, (a) is a front view, and (b) is an operation explanatory view.

FIG. 18 is an enlarged cross-sectional view of an oil mist removing device portion of a conventional example.

FIG. 19 is an exploded perspective view of the above.

FIG. 20 is a front view of a conventional fan used in the above.

FIG. 21 is a perspective view of a comparative example.

FIG. 22 is an operation explanatory view of the above.

[Explanation of symbols]

 9 Casing 10 Motor shaft 12 Guide vane body 13 Disc part 14 Ring-shaped plate part 15 Opening part 16 Blade part 16a Bent part 16b Outer part 16c Inner part 16d Front end edge 16e Rear end edge 17 Rear plate 18 Front plate 19 Hole part 20 Guide vane 20 24 Inner peripheral wall

Claims (2)

[Claims] 1. A ring-shaped plate portion having an opening in the center is disposed in front of a disk portion fixed to a motor shaft so as to face between the ring-shaped plate portion and the disk portion in a front view. A plurality of blades that are bent in a circular shape are installed in a radial pattern, and the outer side of the bent portion of the blade that is bent in a V shape projects outward from the outer peripheral edge of the disk portion and is bent in a V shape. The outer side of the bent portion of the blade portion is twisted with respect to the inner side of the bent portion to incline the front end edge and the rear end edge of the outer side portion of the bent portion with respect to the rotation direction. A fan characterized in that the distance from the outer end of the front edge of the portion outside the bent portion to the motor shaft is equal to or greater than the distance from the outer end of the rear edge of the portion outside the bent portion to the rotating shaft. 2. A front plate having a diameter smaller than that of the rear plate is arranged in front of a large-diameter rear plate having a hole in the center, and a plurality of guide vanes are provided between the front plate and the rear plate. A guide vane body is formed, the fan according to claim 1 is arranged in the casing, and the guide vane body is arranged after the fan in the casing,
The part projecting outward from the bent part of the fan faces the front surface of the outer peripheral part of the rear plate of the guide blade, and the inner peripheral wall of the casing surrounds the fan and the outer periphery of the guide blade, and the rear plate of the guide blade is fanned. An oil mist removing device using a fan, wherein the oil mist removing device is arranged so as to face a rear edge of an outer portion of the blade portion of the blade.