KR102482413B1 - Fan Motor - Google Patents

Abstract

The fan motor includes a motor, an impeller, a housing, and a diffuser. The diffuser has a plurality of cross-flow vanes on the outer surface of the diffuser body, and the motor has a motor space formed therein, and air passing between the diffuser and the housing is an inner guide to guide; It includes a stator and a rotor accommodated in the motor space, and the inner guide is spaced apart from each of the diffuser and the housing and has a hollow body in which the motor space is formed; An axial flow type vane provided on an outer surface of the hollow body and positioned after the shaft flow type vane in the air flow direction, and a gap is formed between the hollow body and the diffuser, through which a part of the air guided by the mixed flow type vane passes, , The motor space forms an inner flow path through which air introduced through the gap passes, an outer flow path is formed between the outer surface of the hollow body and the housing, and the air passing through the diffuser is diverged from the gap to the inner flow path and the outer flow path. It is exhausted after passing through each of the passages.

Description

Fan Motor

The present invention relates to a fan motor, and more particularly, to a fan motor having vanes for guiding air.

The fan motor may be installed in an electric appliance such as a vacuum cleaner or a hair dryer to generate air flow.

Such a fan motor may include a motor and a fan (a blower or an impeller) that is rotated by the motor to flow air.

When the fan motor is installed in a home appliance such as a vacuum cleaner, it may generate a suction force that draws air into the dust collector.

When the fan motor is installed in a home appliance such as a hair dryer, it may generate a blowing force that pressurizes air to the heater.

An example of such a fan motor may include a motor housing, a stator installed in the motor housing, a rotor rotated by the stator, and a rotation shaft on which the rotor is mounted. The rotating shaft of the fan motor may be rotatably supported by at least one bearing, and the rotating shaft may be rotated at high speed while being supported by the bearing.

The performance of the fan motor may deteriorate when the internal temperature of the fan motor rises, and it is preferable that the internal temperature of the fan motor is not overheated.

The fan motor is capable of dissipating heat from the stator and rotor by sucking air exhausted from the outside of the fan motor into the fan motor after flowing in the impeller, and an example of such a fan motor is described in Korean Patent Registration Publication 10-1924591 B1 ( Announced on December 03, 2018).

The fan motor includes an inner housing having a space therein; Including the outer housing surrounding the outer circumference of the impeller and the outer circumference of the inner housing

And, an air passage is formed between the outer circumferential surface of the inner housing and the inner circumferential surface of the outer housing to guide the air blown from the impeller to be discharged to the air outlet. A first opening communicating the outside of the inner housing with the space is formed in the inner housing, and at least one second opening communicating the space and the air passage is formed.

In the fan motor, external air of the fan motor may flow into the space through the first opening to dissipate heat from the stator and the rotor, and air passing through the space may flow into the air passage through the second opening. It can be mixed with the air flowing through the air passage.

However, in the fan motor according to the prior art as described above, since the air discharged through the air discharge port of the fan motor is refluxed into the inner housing through the first opening, a separate free space is provided around the fan motor for circulating the air. required, and the space utilization around the fan motor is low.

Republic of Korea Registered Patent Publication No. 10-1924591 B1 (published on December 03, 2018)

An object of the present invention is to provide a fan motor with improved cooling performance while minimizing loss in a passage through which air passes.

Another object of the present invention is to provide a fan motor capable of being compact.

In the fan motor according to an embodiment of the present invention, a flow path through which air can pass is formed between a housing positioned outside the motor and the motor, and air flowing from an impeller passes through the flow path formed between the housing and the motor. The motor can be cooled.

The motor further includes a vane positioned in the flow path, and the vane may guide air inside the housing.

The fan motor may include a plurality of first vanes and a plurality of second vanes, and the plurality of second vanes may be positioned after the plurality of first vanes in an air flow direction.

The plurality of first vanes may be formed in a diffuser for guiding air flowing from an impeller, and the plurality of second vanes may be provided on an outer surface of the motor.

Each of the plurality of first vanes may be a mixed-flow type vane. Each of the plurality of second vanes may be an axial flow type vane.

The mixed-flow vane may be formed to be inclined at a predetermined angle. The divergent vane may include a leading edge and a trailing edge. A distance between the leading edge of the mixed-flow vane and the rotating shaft may be shorter than a distance between the trailing edge of the mixed-flow vane and the rotating shaft. The mixed-flow vane may be formed in a generally curved shape between a leading edge and a trailing edge. The mixed-flow vane may have an arc shape convexly bent toward the axial flow-type vane.

Each of the mixed-flow vanes may be formed gradually away from other adjacent mixed-flow vanes as the trailing edge thereof gets closer. That is, the distance between the trailing edges of adjacent cross-flow vanes may be longer than the distance between the leading edges.

The divergent vane may include a pair of guide surfaces having a leading edge and a trailing edge. One surface of the pair of guide surfaces may face an outer surface of the impeller, and the other surface of the pair of guide surfaces may face the axial flow type vane. Each of the pair of guide surfaces may be formed in a convex shape toward the axial flow type vane.

The axial flow type vane may include a leading edge and a trailing edge, and a distance between the leading edge of the axial flow type vane and the rotating shaft may be equal to a distance between the trailing edge of the axial flow type vane and the rotating shaft. The axial flow type vane may be formed in a generally curved shape between a leading edge and a trailing edge. The axial flow type vane may have an arc shape convexly bent toward the mixed flow type vane.

Each of the axial flow type vanes may gradually move away from other adjacent axial flow type vanes as it gets closer to its trailing edge. That is, the distance between the trailing edges of adjacent axial flow type vanes may be longer than the distance between the leading edges.

The axial flow type vane may include a pair of guide surfaces having a leading edge and a trailing edge. One surface of the pair of guide surfaces may face the mixed-flow vane, and the other surface of the pair of guide surfaces may face the air outlet. Each of the pair of guide surfaces may be formed in a convex shape toward the mixed-flow vane.

The curvature of the mixed flow type vanes may be smaller than the curvature of the axial flow type vanes.

A length between the leading edge and the trailing edge of the mixed flow type vane may be shorter than a length between the leading edge and the trailing edge of the axial flow type vane.

The mixed-flow vane as described above can efficiently increase the static pressure while appropriately maintaining the natural flow of the swirling flow generated from the impeller without rapidly changing the flow direction of the air.

The axial flow type vane may have a lower static pressure rise than the mixed flow type vane, and may be formed to induce a swirling flow direction of air guided by the mixed flow type vane in an axial direction as much as possible. In this case, it is possible to minimize the air swirling inside the fan motor for a long time, and the axial flow type vanes can help the air to be quickly exhausted to the outside of the fan motor.

In this case, air flowing from the impeller may be dispersed into the passage formed between the motor and the housing and the gap formed between the motor and the diffuser.

Air passing through the passage may radiate heat from the motor while passing through the outside of the motor, and air passing through the gap may radiate heat from the motor while passing through the inside of the motor.

That is, the fan motor may have two passages through which the motor dissipates heat after the diffuser. These two passages may be branched with the hollow body therebetween at a position after the diffuser in the air flow direction.

The fan motor includes a motor for rotating a rotating shaft; an impeller connected to the rotating shaft; a housing having a space in which the impeller is rotatably accommodated; A diffuser may be included to increase the static pressure of the air flowing from the impeller.

The diffuser may be accommodated in the space. The diffuser may include a plurality of cross-flow vanes on an outer surface of the diffuser body.

The motor may include an inner guide, a stator, and a rotor.

A motor space may be formed inside the inner guide. The inner guide may guide air passing between the diffuser and the housing.

The stator may be accommodated in the motor space.

The rotor may be rotatably accommodated inside the stator. The rotor may be mounted on the rotating shaft.

The inner guide includes a hollow body; A plurality of axial flow type vanes may be included. .

The hollow body may be spaced apart from each of the diffuser and the housing, and the motor space may be formed inside the hollow body.

The plurality of axial flow type vanes may be provided on an outer surface of the hollow body. The plurality of axial flow type vanes may be positioned in a flow path formed between an outer surface of the hollow body and an inner surface of the housing.

The plurality of axial flow type vanes may be positioned after the share flow type vanes in an air flow direction.

A gap may be formed between the hollow body and the diffuser, through which a part of the air guided by the mixed-flow vanes passes.

The motor space may form an inner passage through which air introduced through the gap passes.

An outer flow path may be formed between the outer surface of the hollow body and the housing.

The air that has passed through the diffuser may be diverged from the gap and may be exhausted after passing through each of the inner and outer flow passages.

The plurality of axial flow type vanes may be formed on an outer surface of the hollow body and may be positioned in the outer flow path.

In the fan motor configured as described above, flow path loss can be minimized and air passing through the diffuser can be exhausted more quickly than when all of the air passing through the diffuser passes through the inside of the motor.

The fan motor configured as described above may have higher cooling performance than when all of the air passing through the diffuser is exhausted to the outside without passing through the inside of the motor.

That is, the present invention can increase efficiency while minimizing flow loss by dispersing the air guided to the diffuser into the inner and outer flow passages, and at the same time increasing efficiency by preventing overheating of the motor.

An outer diameter of the impeller may be smaller than an inner diameter of the hollow body. When the outer diameter of the impeller is small, the inner and outer diameters of the portion of the housing surrounding the outer circumference of the impeller may also be small, and in this case, the fan motor may be compact.

The number of the axial flow type vanes may be greater than the number of the mixed flow type vanes.

One end of the hollow body may be located in the space of the housing and may be spaced apart from the diffuser in an axial direction. A gap may be formed between one end of the hollow body and the diffuser through which some of the air guided to the diffuser passes to be introduced into the motor space.

The axial flow type vane may include a leading edge closer to one end of the hollow body and a trailing edge closer to the other end of the hollow body.

The axial flow type vane may include an inner end protruding from an outer circumference of the hollow body in a radial direction and an outer end fixed in contact with an inner circumference of the housing in a radial direction.

A radial distance between the inner end and the rotating shaft may be constant without being different along an axial direction.

The hollow body may include an inner body accommodated in the space and an outer body positioned outside the space.

The inner body may include a stator heat dissipation area positioned between an outer circumference of the stator and an inner circumference of the housing in a radial direction.

The axial flow vane may be accommodated between an outer circumference of the inner body and an inner circumference of the housing.

The housing may include an impeller housing, an axial flow vane housing, and a mixed flow vane housing.

The impeller housing may surround an outer circumference of the impeller.

The axial flow type vane housing portion may be in contact with the axial flow type vane and may be larger than the impeller housing portion.

The mixed flow type vane housing unit may connect the impeller housing unit and the axial flow type vane housing unit. The mixed flow vane housing may surround an outer circumference of the diffuser.

The axial flow type vane housing part may gradually expand as it is closer to the axial flow type vane housing part.

The axial flow type vane housing portion may have the same diameter in an axial direction.

According to an embodiment of the present invention, while the air guided to the diffuser is distributed to the inner and outer passages, it is possible to efficiently exhaust air and dissipate heat from the motor, respectively.

In addition, since the outer diameter of the impeller is smaller than the inner diameter of the hollow body, it is possible to compact the impeller and the impeller housing.

In addition, a plurality of axial flow type vanes are positioned after the plurality of mixed flow type vanes in the air flow direction, so that the static pressure can be efficiently increased while maintaining the natural flow of the swirling flow generated in the impeller.

In addition, the axial flow type vanes guide the swirling flow direction of the air guided by the mixed flow type vanes in the axial direction as much as possible, thereby minimizing the fact that the air swirls inside the fan motor for a long time, and quickly moving the air out of the fan motor. can help you get exhausted.

1 is a cross-sectional view showing the inside of a fan motor according to an embodiment of the present invention;
2 is a perspective view of the diffuser shown in FIG. 1;
3 is a perspective view of the inner guide shown in FIG. 1;

Hereinafter, specific embodiments of the present invention will be described in detail with drawings.

1 is a cross-sectional view showing the inside of a fan motor according to an embodiment of the present invention, FIG. 2 is a perspective view of a diffuser shown in FIG. 1 , and FIG. 3 is a perspective view of an inner guide shown in FIG. 1 .

The fan motor includes a motor (M) for rotating the rotary shaft (1), an impeller (2) connected to the rotary shaft (1), and a diffuser (3) for increasing the static pressure of the air flowed by the impeller (2); It may include a housing 4 in which a space S in which the impeller 2 is rotatably accommodated is formed.

The rotating shaft 1 may be disposed long inside the housing 4 . As an example of the rotation shaft 1, all of the rotation shaft 1 may be accommodated inside the housing 4. Another example of the rotating shaft 1 is a portion of the rotating shaft 1 accommodated inside the housing 4, and the rest of the rotating shaft 1 may extend to the outside of the housing 4.

The rotating shaft 1 may be connected to the rotor 9 of the motor M and rotate together with the rotor 9 .

The rotating shaft 1 may be rotatably supported by at least one bearing 11 or 12, and the bearing 11 or 12 may be mounted on at least one bearing housing. The bearings 11 and 12 may rotatably support the rotating shaft 1 while being accommodated and supported in the bearing housing.

The bearings 11 and 12 may be rolling bearings such as ball bearings, roller bearings and needle bearings, or gas bearings.

When the bearing is a rolling bearing, the rolling bearing may include an inner ring fixed to the rotating shaft, an outer ring fixed to the bearing housing, and a rolling member disposed between the inner ring and the outer ring.

When the bearing is a gas bearing, the gas bearing is supported by the bearing housing and may have a gap with the rotary shaft 1 .

The fan motor may include a plurality of bearings 11 and 12.

One example of the plurality of bearings 11 and 12 can be disposed spaced apart with the rotor 9 interposed therebetween, and in this case, any one of the plurality of bearings 11 and 12 (11) is the impeller 2 and It may be mounted on the rotating shaft 1 to be located between the rotor 9, and the other one 12 of the plurality of bearings 11 and 12 may be mounted on the opposite side of the impeller 2 of the rotating shaft 1, , The rotor 9 may be positioned between a plurality of bearings 11 and 12.

In this case, the motor M may include a first bearing housing 13 supporting one 11 of a plurality of bearings 11 and 12 . The first bearing housing 13 may be coupled to the housing 4 or fixed to an inner guide 5 constituting the motor M, in particular, the motor M.

Also, the motor M may include a second bearing housing 14 supporting the other one 12 of the plurality of bearings 11 and 12 . The second bearing housing 14 may be formed on the inner guide 5 .

As another example of the plurality of bearings 11 and 12, each of the plurality of bearings 11 and 12 may be mounted on the rotating shaft 1 so as to be positioned between the impeller 2 and the rotor 9. A plurality of bearings 11 and 12 may be mounted on the rotating shaft 1 to be spaced apart in the axial direction.

In this case, the motor M may include one first bearing housing 13 supporting a plurality of bearings 11 and 12 together. In this case, a separate second bearing housing 14 does not need to be formed on the inner guide 5 .

The motor M can dissipate heat in three dimensions by an inner passage P3 formed inside the motor M and an outer passage P4 formed outside the motor M, and the motor M will be described later. to explain in detail.

The impeller 2 may be connected to the rotation shaft 1 . The impeller 2 may rotate inside the housing 4 when the rotating shaft 1 rotates.

The impeller 2 may include a plurality of blades 21 and a hub 22 from which the plurality of blades 21 protrude.

The plurality of blades 21 may be formed to protrude from the outer circumference of the hub 22, and the plurality of blades 22 may be formed to be spaced apart from each other in the circumferential direction.

The impeller 2 may be a cross-flow type impeller that sucks air in the axial direction and flows it in an inclined direction (D) between the axial direction (L) and the radial direction (R).

The hub 22 may be formed in a three-dimensional shape, and may be formed in a shape whose outer diameter gradually increases as it approaches the rotor 9 . An impeller passage P1 may be formed between the outer circumference of the hub 22 and the inner circumference of the housing 4 to forcibly flow the air sucked through the air inlet 41 to the mixed-flow type vane 32 described later.

When the outer diameter D1 of the impeller 2 is small, the fan motor can easily rotate the impeller 2 at a higher speed, and the outer diameter D1 of the impeller 2 is smaller than the outer diameter of the motor M. can

The outer diameter D1 of the impeller 2 may be approximately 40% to 60% of the outer diameter of the motor M.

If the outer diameter D1 of the impeller 2 is small, the fan motor can also reduce the size of the portion surrounding the impeller 2 (ie, the impeller housing portion 43), and the outer diameter D1 of the impeller 2 When is small, the fan motor can be high-speed and compact.

The outer diameter D1 of the impeller 2 may be smaller than the inner diameter D2 of the hollow body 6, especially the inner diameter of the inner guide 5 of the motor M.

Here, the outer diameter D1 of the impeller 2 may be defined as the maximum outer diameter of the impeller 2, and among the blades 21 of the impeller 2, the part furthest from the rotary shaft 1 in the radial direction and the rotary shaft It can be defined as twice the distance to the axis center of (1).

The diffuser 3 may be arranged to be located inside the housing 4 . The diffuser 3 may be accommodated in the space S of the housing 4 together with the impeller 2 .

The diffuser 3 may be positioned after the impeller 2 in the air flow direction to convert the dynamic pressure of the air flowing in the impeller 2 into a static pressure. The diffuser 3 may include a diffuser body 31 and a plurality of divergent vanes 32 protruding from an outer surface of the diffuser body 31 .

The diffuser body 31 may be formed in a shape in which the size gradually increases as the distance from the impeller 2 increases. An approximate cross-sectional shape of the diffuser body 31 may be a trapezoidal shape or a shape close to the trapezoidal shape. The outer circumferential surface of the diffuser body 31 may be formed as a convex curved surface toward the inner circumferential surface of the housing 4 .

Referring to FIG. 2 , a first line between an extension line E1 extending from the outer circumferential surface of the diffuser body 31 toward the axial center C of the diffuser body 31 and the axial center C of the rotation shaft 1 The angle may be an acute angle.

This first angle may be a factor determining the flow direction of the air flowing from the impeller 2 . The first angle may be 40° to 80°.

When the first angle exceeds 80°, the diffuser 3 may be a centrifugal diffuser that mainly guides the air flowing from the impeller 2 in the radial direction R.

On the other hand, as described above, when the first angle is 40 ° to 80 °, the diffuser 3 moves the air flowed from the impeller 2 in the inclined direction (D) between the axial direction (L) and the radial direction (R). It may be a mixed flow diffuser that guides to

The outer diameter of the diffuser body 31 may be larger than the air inlet 41 of the housing 4 and smaller than the maximum outer diameter of the housing 4 . Here, the outer diameter of the diffuser body 31 may be defined as the maximum outer diameter of the diffuser body 31 .

The diffuser 3 may have a rotation shaft through hole 33 through which the rotation shaft 1 passes. The rotation shaft through hole 33 may be formed in the diffuser body 31 .

A diffuser passage P2 may be formed between the outer circumference of the diffuser body 31 and the inner circumference of the housing 4 to gradually increase the static pressure of air pumped from the impeller 2 . The diffuser passage P2 may be after the impeller passage P1 in the air flow direction.

A plurality of mixed-flow vanes 32 may be disposed to protrude from the outer surface of the diffuser body 31 and may be spaced apart from each other in a circumferential direction.

A plurality of mixed-flow vanes 32 may be formed so as not to abruptly change the flow direction. To this end, each of the plurality of mixed-flow type vanes 32 may be formed long in an oblique direction with respect to the axis center C as a whole. In addition, the curvature of each of the plurality of mixed-flow vanes 32 may be formed to be small. In this case, the curvature of the plurality of mixed-flow vanes 32 may be smaller than that of the axial flow-type vanes 7 .

The divergent vanes 32 may be formed to be inclined at a predetermined angle with respect to the axial direction on the outer circumference of the diffuser body 31 . The cross-flow type vane 32 may include a leading edge 34 and a trailing edge 35, and the radial distance between the leading edge 34 of the cross-flow type vane 32 and the rotating shaft 1 is a cross-flow type. It may be shorter than the radial distance between the trailing edge 35 of the vane 32 and the axis of rotation 1 . The divergent vane 32 may be formed in a shape bent as a whole between the leading edge 34 and the trailing edge 35 . The divergent flow type vane 32 may have an arc shape convexly bent toward the axial flow type vane 7 to be described later.

The length between the leading edge 34 and the trailing edge 35 of the divergent flow type vane 32 may be shorter than the length between the leading edge 74 and the trailing edge 74 of the axial flow type vane 7 .

Each of the mixed-flow vanes 32 may gradually move away from other adjacent mixed-flow vanes 32 as they get closer to the trailing edge 35 . The plurality of mixed-flow vanes 32 may gradually increase as the distance from other adjacent mixed-flow vanes approaches the trailing edge 35 .

That is, the distance between the trailing edges 35 of the adjacent mixed-flow vanes 32 may be longer than the distance between the leading edges 34 of the adjacent mixed-flow vanes 32 .

While the air passes between the pair of adjacent mixed-flow vanes 32, the dynamic pressure may gradually decrease and the static pressure may gradually increase.

The divergent vane 32 may include a pair of guide surfaces 36 and 37 having a leading edge 34 and a trailing edge 35 . One surface of the pair of guide surfaces 36 and 37 may face the outer circumference of the impeller 2, and the other surface of the pair of guide surfaces 36 and 37 may face the axial flow type vane 7. Each of the pair of guide surfaces 36 and 37 may be formed in a convex shape toward the axial flow type vane 7 .

The housing 4 may form the outer appearance of the fan motor. The housing 4 may surround the outer circumference of the impeller 2 and the diffuser 3, and the housing 4 may protect the impeller 2, the diffuser 3, and the motor M.

An air inlet 41 through which external air is sucked may be formed on one side of the housing 4 . The housing 4 may have an air outlet 42 larger than the air inlet 41 formed on the opposite side of the air inlet 41 . An external flow path P4 through which air guided to the diffuser 3 passes may be formed between the housing 4 and the motor M. The outer passage P4 may be defined as a space between the outer circumference of the hollow body 6 constituting the motor M and the inner circumference of the housing 4 .

The housing 4 includes an impeller housing portion 43 and an axial flow type vane housing portion 44; A mixed-flow vane housing portion 45 may be included.

The impeller housing part 43 may surround the outer circumference of the impeller 2 . The air inlet 41 may be formed at one end of the impeller housing part 43 .

The axial flow type vane housing portion 44 may come into contact with the axial flow type vane 7 . The axial flow type vane housing part 44 may be larger than the impeller housing part 43 .

The axial flow type vane housing portion 44 may have the same diameter in the axial direction.

The axial flow type vane housing part 44 may have a hollow cylindrical shape with a constant diameter as a whole, and its diameter may be the same as the maximum diameter of the mixed flow type vane housing part 45, and a diameter greater than the diameter of the hollow body 6 to be described later. can be big

The mixed flow vane housing part 45 may surround the outer circumference of the diffuser 3, and the plurality of mixed flow vanes 32 may be positioned between the spiral vane housing 45 and the diffuser body 31. can

The mixed-flow vane housing part 45 may be formed in a shape capable of connecting the impeller housing part 43 and the axial flow-type vane housing part 44 .

The mixed-flow type vane housing portion 45 may be formed to gradually expand as it is closer to the axial-flow type vane housing 44 in the axial direction.

The motor (M) includes an inner guide (5) for guiding the air passing through the diffuser (3); a stator 8 installed inside the inner guide 5; It includes a rotor 9 rotatably accommodated inside the stator 8 and mounted on the rotational shaft 1 .

The inner guide 5 may include a hollow body 6 and a plurality of axial flow type vanes 7 .

A motor space in which the stator 8 and the rotor 9 are accommodated may be formed inside the hollow body 6 .

The hollow body 6 may be spaced apart from each of the housing 4 and the diffuser 3 .

The hollow body 6 may be spaced apart from the housing 4 in an axial direction (L) and a radial direction (R).

The hollow body 6 may be spaced apart from the diffuser 3 in the axial direction (L).

One end 61 of the hollow body 6 may be located in the space S of the housing 4. One end 61 of the hollow body 6 may be spaced apart from the diffuser 3 in the axial direction L. One end 61 of the hollow body 6 may be after the divergent vane 32 in the air flow direction.

Between one end 61 of the hollow body 6 and the diffuser 3, a gap G through which air guided by the mixed-flow type vanes 32 passes may be formed.

The motor space of the hollow body 6 may form an inner passage P3 through which air passes through the gap G, and an outer passage P4 is formed between the outer surface of the hollow body 6 and the housing 4. can form.

The inner flow path P3 may be formed to extend through the inside of the hollow body 6 in the axial direction, and the air introduced into the inner flow path P3 passes through the inner flow path P3 while passing through the stator 8 and the rotor ( After cooling 9), it can be exhausted to the outside of the hollow body (6). The air introduced into the inner passage P3 can directly cool the stator 8 and the rotor 9 by air cooling, respectively, while passing through the air gap between the stator 8 and the rotor 9 .

Air cooling the stator 8 and the rotor 9 while passing through the inner passage P3 may be exhausted to the outside of the fan motor through the motor exhaust port 65 formed in the hollow body 6 .

The air that has passed through the diffuser 3 can be branched to the inside and outside of the hollow body 6 at the gap G, and can be exhausted after passing through each of the inner flow path P3 and the outer flow path P4. .

The outer passage P4 may be formed in a substantially hollow cylindrical shape between the hollow body 6 and the housing 4, and the air that does not flow into the gap G in the air guided by the diffuser 3 The hollow body 6 may be cooled while moving along the outer passage P4. When the motor is driven, the heat of the stator 8 can be transferred to the hollow body 6 and the axial flow type vane 8, and the air passing through the outer passage P4 passes through the hollow body 6 and the axial flow type vane ( 8) can be cooled by air-cooling, and the heat of the stator 8 can be transferred to the air passing through the outer flow path P4 through the hollow body 6 and the axial flow type vane 8.

The air guided to the axial flow type vane 7 while passing through the outer flow path P4 gradually reduces its rotation component while being guided to the axial flow type vane 7, and finally the air between the hollow body 6 and the housing 4 The air may be exhausted to the outside of the fan motor through the air discharge port 42 .

That is, the air flowing from the impeller passage P1 to the deryuzer passage P2 is guided to the divergent vane 32, and then passes through the gap G to the inner passage P3 and the outer passage P4 through the hollow body ( 6), and can be finally dispersed and exhausted to the outside of the fan motor through each of the inner flow path P3 and the outer flow path P4.

In this embodiment, the air that has passed through the diffuser 3 is guided in the direction that the multi-flow type vanes 32 guide. As the air flows along the direction of the multi-flow type vanes 32, the guided air moves along the inside of the hollow body 6 and It can be dispersed to the outside of the hollow body (6).

The other end 62 of the hollow body 6 may face the outside of the space S. The other end 62 of the hollow body 6 may be located opposite one end 61 of the hollow body 6 in the axial direction (L). The other end 62 of the hollow body 6 may be located outside the space S.

The hollow body 6 may include an inner body 63 accommodated in the space S and an outer body 64 positioned outside the space S.

The inner body 63 may include one end 61 of the hollow body 6 .

The inner body 63 may include a stator heat dissipation area located between the outer circumference of the stator 8 and the inner circumference of the housing 4 in the radial direction R.

The outer body 64 may include the other end 62 of the hollow body 6 .

The hollow body 6 may have at least one motor exhaust port 65 through which air cooling the rotor 8 and the stator 9 is exhausted to the outside of the hollow body 6 while passing through the inner passage P3. .

The motor exhaust port 65 is preferably not formed on the inner body 63 of the hollow body 6, and is preferably formed on the outer body 64.

A plurality of axial flow type vanes 7 protrude on the outer surface of the hollow body 6 and can induce the rotational component of the flow in the axial direction. A plurality of axial flow type vanes 7 may be disposed on the outer circumference of the inner body 63 .

The axial flow vane 7 may include a leading edge 74 and a trailing edge 75 .

The distance between the leading edge 74 of the axial flow type vane 7 and the rotating shaft 1 may be the same as the distance between the trailing edge 75 of the axial flow type vane 7 and the rotating shaft 1 .

The axial flow type vane 7 may be formed in an overall curved shape between the leading edge 74 and the trailing edge 75 . The axial flow type vanes 7 may have an arc shape convexly bent toward the mixed flow type vanes 32 .

The number of the axial flow type vanes 7 may be greater than the number of the mixed flow type vanes 32 . The axial flow type vane 7 can mainly switch the flow direction from the centrifugal direction to the axial direction, and is configured to dissipate the heat transferred through the hollow body 6, and the heat transfer area of the plurality of axial flow type vanes 7 It is desirable that it is formed as wide as possible. For example, when 13 mixed flow type vanes 32 are formed, 16 axial flow type vanes 7 may be formed.

As each of the axial flow type vanes 7 gets closer to its trailing edge 75, it may gradually move away from other adjacent axial flow type vanes. That is, the distance between the trailing edges 75 of adjacent axial flow type vanes 7 may be longer than the distance between the leading edges 74 .

The axial flow vane 7 may include a pair of guide surfaces 76 and 77 having a leading edge 74 and a trailing edge 75 . One surface 76 of the pair of guide surfaces 76 and 77 may face the mixed-flow vane 32, and the other surface 77 of the pair of guide surfaces 76 and 77 may face the air outlet 42. can be directed to Each of the pair of guide surfaces 76 and 77 may be formed in a convex shape toward the divergent vane 32 .

The mixed-flow type vanes 32 may function as a first-stage vane diffuser, and the axial-flow type vanes 7 may function as a two-stage vane diffuser for guiding air passing through the first-stage vane diffuser. That is, the fan motor of the present embodiment may include two vane diffusers, and the static pressure is highly reliably increased by the first-stage vane diffuser and the two-stage vane diffuser, and the flow direction of the air flow is not rapidly changed, but is gently multi-staged. can be converted to

In the fan motor of this embodiment, between the impeller 2 and the air outlet 42, the mixed flow type vanes 32 and the axial flow type vanes 7 may be sequentially disposed, and the impeller 2 to the air outlet 42 A vaneless section (ie, a section in which no vane exists) in between can be minimized.

The axial flow type vane 7 may have a lower static pressure rise than the mixed flow type vane 32 and may be formed to induce the swirling flow of air guided by the mixed flow type vane 32 in the axial direction as much as possible. In this case, it is possible to minimize the air swirling inside the fan motor for a long time, and the axial flow type vanes 7 help the air to be quickly exhausted out of the fan motor.

The axial flow vane 7 may include an inner end protruding from the outer circumference of the hollow body 6 in the radial direction and an outer end fixed in contact with the inner circumference of the housing 4 in the radial direction.

When assembling the fan motor, when the motor M, in particular, the inner guide 5 is inside the housing 4, the outer end of the axial flow type vane 7 can come into contact with the inner circumference of the housing 4, , The inner guide 5 may be fitted to the inner circumference of the housing 4. That is, the axial flow type vane 7 may function as a structure supporting the motor M to the housing 4 .

The stator 8 may be disposed inside the inner guide 5 , in particular, the hollow body 6 . The stator 8 may include a plurality of coils 84.

The stator 8 may be mounted on the inner guide 5, particularly the hollow body 6, to rotate the rotor 9. The stator 8 may be mounted on the hollow body 6 . The stator 8 may be mounted to the hollow body 6 with a fastening member such as a screw or fixed with an adhesive member such as an adhesive. The stator 8 may be formed in a hollow cylindrical shape as a whole. The stator 8 may be mounted around the outer circumference of the rotor 9 on the inner circumference of the hollow body 6 .

The stator 8 may be composed of a combination of a plurality of members. The stator 8 may include a stator core 81, a pair of insulators 82 and 83 coupled to the stator core 81, and a coil 84 disposed on the insulators 82 and 83. there is.

A plurality of coils 84 may be provided, and the plurality of coils 84 may be spaced apart along the outer circumference of the rotor 9 . In the stator 8 , gaps through which air may pass may be formed between adjacent coils 84 . These gaps can be radially directed towards the axis of rotation 1 in the radial direction R.

The rotor 9 may be located inside the stator 8 .

The rotor 9 may be mounted to surround a part of the rotating shaft 1 . The rotor 9 may be rotatably positioned inside the stator 8 . The rotor 9 may be formed in a hollow cylindrical shape.

The rotor 9 may be mounted to surround a part between one end and the other end of the rotation shaft 1 .

The rotor 9 may include a magnet 92 and a pair of end plates 93 and 94 fixing the magnet 92 . The rotor 9 may further include a rotor core 91 fixed to the rotation shaft 1 , and a magnet 92 may be installed on the rotor core 91 .

The fan motor configured as described above includes the air inlet 41, the impeller passage P1, the diffuser passage P2, the outer passage P4, the first passage leading to the air outlet 42, and the air inlet 41. ), an impeller passage (P1), a diffuser passage (P2), a gap (G), an inner passage (P3), and a second passage leading to the exhaust port (65). Through the 2 passages, air can be rapidly circulated while dissipating heat from the motor M three-dimensionally.

The above description is merely an example of the technical idea of the present invention, and various modifications and variations can be made to those skilled in the art without departing from the essential characteristics of the present invention.

Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain, and the scope of the technical idea of the present invention is not limited by these embodiments.

The protection scope of the present invention should be construed according to the claims below, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

1: rotary shaft 2: impeller
3: diffuser 4: housing
5: inner guide 6: hollow body
7: axial vane 8: stator
9: rotor 31: diffuser body
32: divergent vane G: gap
M: motor P3: inner passage
P4: outer passage S: space

Claims (10)

a motor that rotates a rotating shaft;
an impeller connected to the rotating shaft;
a housing formed with a space in which the impeller is rotatably accommodated;
a diffuser accommodated in the space and having a diffuser vane on an outer surface of the diffuser body;
An axial flow vane positioned after the divergent flow vane in the air flow direction;
The mixed-flow vane includes a leading edge and a trailing edge,
The fan motor of claim 1 , wherein a distance between a leading edge of the mixed-flow vane and the rotating shaft is shorter than a distance between a trailing edge of the mixed-flow vane and the rotating shaft. According to claim 1,
A gap through which air passes is formed in the motor,
The gap is formed toward the fan motor between the mixed flow type vane and the axial flow type vane. According to claim 1,
the motor
An inner guide with a motor space formed therein;
a stator accommodated in the motor space;
A rotor rotatably accommodated inside the stator and mounted on the rotation shaft,
A gap through which air passes is formed between the inner guide and the diffuser,
The gap is a fan motor facing between the mixed flow type vane and the axial flow type vane. According to claim 3,
The inner guide has one end spaced apart from the diffuser in the axial direction,
The gap is a fan motor formed between one end of the inner guide and the diffuser. According to claim 1,
Each of the axial flow vanes includes a leading edge and a trailing edge,
The divergent vane is convex toward the axial flow vane between the leading edge and the trailing edge,
The axial flow type vane is a fan motor in which a gap between a leading edge and a trailing ring edge is convex toward the mixed flow type vane. According to claim 1,
The number of the axial flow type vanes is greater than the number of the mixed flow type vanes. According to claim 1,
The fan motor of claim 1 , wherein a length between a leading edge and a trailing edge of the mixed flow type vane is shorter than a length between the leading edge and the trailing edge of the axial type vane. According to claim 1,
The fan motor in which the mixed-flow vanes are elongated in an oblique direction laid obliquely with respect to the center of the shaft. According to claim 1,
The curvature of the mixed-flow type vanes is smaller than the curvature of the axial-flow type vanes. According to claim 1,
the housing
An impeller housing portion surrounding an outer circumference of the impeller;
An axial flow vane housing portion that is in contact with the axial flow vane and is larger than the impeller housing portion;
A fan motor comprising a mixed flow vane housing portion connecting the impeller housing portion and the axial flow type vane housing portion and surrounding an outer circumference of the mixed flow type vane.

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