KR20210013680A - Axial fan monolithic type rotor and method manufacturing the same - Google Patents

Abstract

The present invention relates an axial-flow fan integrated rotor and a method for manufacturing the same. The axial-flow fan integrated rotor comprises: a rotor housing which includes a cylindrical part formed in the shpae of a cylinder, a cover part for blocking one end of the cylindrical part, a plurality of wing mounting parts protruding from the outer circumferential surface of the cylindrical part at regular intervals in the circumferential direction, an insertion hole formed through the center of the cover part, and a bushing coupling part extending from the rim of the insertion hole, which is positioned inside the cylindrical part, to have a cylindrical shape; a back yoke ring coupled to the inner circumferential surface of the cylindrical part of the rotor housing; a plurality of magnetic members coupled to the back yoke ring at regular intervals; a bushing coupled to the bushing coupling part of the rotor housing; a rotor shaft positioned in the rotor housing and coupled to the bushing; and a plurality of wings fastened to the wing mounting parts of the rotor housing, respectively, by fastening means. The present invention is simply manufactured and minimizes assembling deformation, thereby having excellent performance.

Description

Axial fan integrated rotor and its manufacturing method {AXIAL FAN MONOLITHIC TYPE ROTOR AND METHOD MANUFACTURING THE SAME}

The present invention relates to an axial fan integrated rotor and a method of manufacturing the same.

With the growth of the IT industry, the supply of thermo-hygrostats installed in computer rooms, super computer rooms, clean rooms, measurement rooms, laboratories, environmental testing rooms, electrical parts assembly rooms, electronic exchanger rooms, and storage warehouses is increasing. A thermo-hygrostat is a multifunctional air conditioner that adjusts the air condition so that various equipment or devices affected by indoor air can operate in the best condition. As a component of such a thermo-hygrostat, an outdoor unit fan installed in the outdoor unit to dissipate heat to the outside is provided, and the efficiency and performance of the thermo-hygrostat depends on the performance of the outdoor unit fan, which is an axial fan.

As an example of the outdoor unit fan, the outdoor unit fan includes blades provided at intervals in the circumferential direction on the outer rotor of the outer rotor type motor. Such an outdoor fan has excellent blowing performance, but the assembling work is complicated because the blades are coupled to the outer rotor by welding, and heat deformation may occur on the blades during welding, and vibration and wind noise are generated when heat deformation occurs. There is this.

It is an object of the present invention to provide an axial fan-integrated rotor with excellent performance by simple manufacturing and minimizing assembly deformation and a manufacturing method thereof.

In order to achieve the object of the present invention, a cylindrical portion in the form of a cylinder, a cover portion blocking one end of the cylindrical portion, a plurality of wing mounting portions protruding at a predetermined interval in the circumferential direction on the outer peripheral surface of the cylindrical portion, and the A rotor housing including an insertion hole formed through the center of the cover portion, and a bush coupling portion extending in a cylindrical shape at an edge of the insertion hole located inside the cylindrical portion; A back yoke ring coupled to an inner peripheral surface of the cylindrical portion of the rotor housing; A plurality of magnet members coupled to the back yoke ring at predetermined intervals; A bush coupled to a bush coupling portion of the rotor housing; A rotor shaft located inside the rotor housing and coupled to the bush; An axial fan-integrated rotor including a plurality of blades each of which is fastened to the blade mounting portions of the rotor housing by fastening means is provided.

Balancing holes are provided at uniform intervals from each other in the circumferential direction at the edge of the cover portion of the rotor housing, and it is preferable that a mass is filled in any of the balancing holes.

The blade mounting portion of the rotor housing is positioned in a longitudinal direction in the circumferential direction of the cylindrical portion, but extended in one direction to each of both ends of the mounting base plate in the longitudinal direction of the mounting base plate extending in a longitudinal direction so as to be inclined to the longitudinal center line of the cylindrical portion. Protruding reinforcing ribs, wing support protrusions protruding from one side of the mounting base plate at intervals, and extending protruding from the other side of the mounting base plate so as to be positioned between the wing support protrusions, and a screw therein It is preferable to include a fastening protrusion provided with a hole.

The bush includes an annular ring-shaped support body having a set length, an annular ring groove formed to have a uniform width and depth on the outer circumferential surface of the support body, and a support body portion located between the annular ring groove and one end of the support body. It is preferable to include a rough surface made of a plurality of fine protrusions formed on the outer circumferential surface.

In addition, the steps of arranging the bush and the back yoke ring inside the rotor housing molding mold and injecting molten aluminum to form the rotor housing; Attaching magnet members to the back yoke ring of the motor housing in a circumferential direction at predetermined intervals; Pressing the rotor shaft into the bush of the rotor housing molded by the insert injection; Coupling the blades to the blade mounting portions of the rotor housing by bolts; The rotor housing includes a step of balancing the rotation of the rotor housing, wherein the rotor housing has a cylindrical portion in the form of a cylinder, a cover portion blocking one end of the cylindrical portion, and a protrusion formed on an outer circumferential surface of the cylindrical portion at a predetermined interval A plurality of wing mounting portions, an insertion hole formed through the center of the cover portion, and a bush coupling portion extending in a cylindrical shape to an edge of the insertion hole located inside the cylindrical portion, and the bag on the inner peripheral surface of the cylindrical portion There is provided a method for manufacturing an axial fan-integrated rotor, wherein a yoke ring is inserted and the bush is inserted into an inner circumferential surface of the bush coupling portion.

Balancing holes are formed at uniform intervals from each other in the circumferential direction at the rim of the cover part of the rotor housing, and it is preferable that a mass is filled in any of the balancing holes to match the balancing.

The bush includes an annular ring-shaped support body having a set length, an annular ring groove formed to have a uniform width and depth on the outer circumferential surface of the support body, and a support body portion located between the annular ring groove and one end of the support body. It is preferable to include a rough surface made of a plurality of fine protrusions formed on the outer circumferential surface.

In the present invention, a plurality of wing mounting parts are provided in the rotor housing, and the blades are fastened to each of the wing mounting parts by bolts, which are fastening means, so that the operation of coupling the blades to the rotor housing is simple. In addition, when the blades are assembled to the rotor housing, the assembly deformation of the blades by heat is prevented and the assembly position of the blades is correct. Due to this, noise generation is minimized when the rotor housing and the blades rotate.

In addition, the present invention manufactures a rotor housing by integrating the back yoke ring and the bush by insert molding, and the magnet members, the rotor shaft, and the blades are respectively coupled to the rotor housing produced by the insert molding, so manufacturing is simple. In addition, the balance holes are filled with masses to adjust the balance, so that the balancing is accurate and the balancing operation is simple, making it suitable for mass production.

In addition, in the present invention, when the bush is provided with an annular ring groove formed to have a uniform width and depth on the outer circumferential surface, and a rough surface made of a plurality of fine protrusions on one side of the outer circumferential surface, the bush is firmly coupled to the rotor housing.

1 is a side view showing an outer rotor type motor provided with an axial fan-integrated rotor according to the present invention;
2 is a front view showing an outer rotor type motor equipped with an axial fan-integrated rotor according to the present invention;
3 is a side view showing a rotor housing constituting an axial fan-integrated rotor according to the present invention;
4 is a front view showing a rotor housing constituting the axial fan-integrated rotor according to the present invention,
5 is a side view showing a partial cross-sectional view of a rotor housing constituting an axial fan-integrated rotor according to the present invention;
6 is a side view showing in partial cross-section a bush constituting the axial fan-integrated rotor according to the present invention;
7 is a flow chart showing an embodiment of a method for manufacturing an axial fan-integrated rotor according to the present invention.

Hereinafter, an embodiment of an axial fan-integrated rotor and a method of manufacturing the same according to the present invention will be described with reference to the accompanying drawings.

1 is a side view showing an outer rotor type motor having an axial fan-integrated rotor according to the present invention. 2 is a front view showing an outer rotor type motor equipped with an axial fan-integrated rotor according to the present invention.

1 and 2, the outer rotor type motor provided with the axial fan-integrated rotor according to the present invention includes a motor frame 100 including a tube-shaped bearing supporter 110, and a bearing supporter 110 The stator 200 coupled to the outer circumferential surface of the present invention enclosing the stator 200 and rotatably coupled to the bearing supporter 110 of the present invention is coupled to one side of the motor frame 100 And a component casing 400 in which a printed circuit board on which electronic components are mounted is mounted.

An embodiment of the axial fan-integrated rotor 300 according to the present invention is a rotor housing 310, a back yoke ring 320, a magnet member 330, a bush 340, a rotor shaft 350, a blade ( 360).

As an example of the rotor housing 310, as shown in FIGS. 3, 4, and 5, the rotor housing 310 has a cylindrical portion 311 in a cylindrical shape, and a cover portion blocking one end of the cylindrical portion 311 (312), a plurality of wing mounting portions 313 protruding at predetermined intervals in the circumferential direction on the outer circumferential surface of the cylindrical portion 311, and an insertion hole (H) formed through the center of the cover portion 312 , It includes a bush coupling portion 314 extending in a cylindrical shape to the edge of the insertion hole (H) located inside the cylindrical portion 311.

It is preferable that the outer rim of the cover part 312 is formed in a curved shape. Balancing holes 315 are preferably provided on the rim of the cover part 312 at uniform intervals from each other in the circumferential direction. The balancing holes 315 are formed on an imaginary circle with uniform intervals from each other. The balancing holes 315 may be formed on the front surface of the cover part 312. As an example of the balancing hole 315, the balancing hole 315 includes a first hole formed to have a uniform inner diameter and depth, and a second hole having the same center line as the first hole and having an inner diameter larger than the inner diameter of the first hole. Include. A mass body (not shown) is filled in any of the balancing holes 315. It is preferable that a plurality of flow generating ribs 316 are provided on the inner side of the cover part 312 with uniform intervals in the radially circumferential direction with the through hole 313 as the center.

The wing mounting portion 313 has a mounting base plate 11 extending in a longitudinal direction in the circumferential direction of the cylindrical portion 311 but extending obliquely to the longitudinal center line of the cylindrical portion 311, and the mounting base plate 11 ) Reinforcing ribs 12 extending in one direction at both ends of the longitudinal direction, and wing support protrusions 13 protruding at intervals from each other on one side of the mounting base plate 11, and the wing support protrusions (13) It extends to the other side of the mounting base plate 11 so as to be positioned between and includes a fastening protrusion 15 having a screw hole 14 therein. The reinforcing ribs 12 are formed on the opposite side of the mounting base plate 11 on which the wing support protrusions 13 are formed. It is preferable that the wing support protrusions 13 are two. The fastening protrusion 15 is formed protruding from the mounting base plate 11 on the opposite surface of the wing support protrusions 13. The screw hole 14 is formed to a predetermined depth inside the fastening protrusion 15 on one side of the mounting base plate 11 on which the wing support protrusions 13 are formed. The wing mounting portions 313 are preferably positioned at a predetermined interval in the circumferential direction on a virtual circle formed along the outer circumferential surface of the cylindrical portion 311, and the inclination angle with the center line of the cylindrical portion 311 is 38 to 42 degrees. It is desirable. It is preferable that the wing mounting portions 313 are five.

The back yoke ring 320 is coupled to the inner peripheral surface of the cylindrical portion 311 of the rotor housing 310. The back yoke ring 320 is formed in a cylindrical shape and has an inner diameter of the cylindrical portion 311 of the rotor housing 310. The back yoke ring 320 is coupled to the inner circumferential surface of the cylindrical portion 311 of the rotor housing 310 in a form in which one end in the longitudinal direction is inserted into the inner surface of the cover portion 312.

The magnet members 330 are plural, and are coupled to the back yoke ring 320 at a predetermined interval.

The bush 340 is coupled to the inside of the bush coupling portion 314 of the rotor housing 310. As an example of the bush 340, the bush 340 has an annular ring-shaped support body 341 having a set length, and an annular ring groove formed to have a uniform width and depth on the outer circumferential surface of the support body 341 ( 342), and a rough surface portion 343 formed of a plurality of fine protrusions formed on the outer peripheral surface of the support body portion 341 located between the annular ring groove 342 and one end of the support body portion 341 . It is preferable that the mounting surface portion 343 is formed by knurling the outer peripheral surface of the support body portion 341.

The rotor shaft 350 is located inside the rotor housing 310, and one end is coupled to the bush 340.

The wings 360 are fastened to the wing mounting portions 313 of the rotor housing 310 by fastening means 370, respectively. As an example of the fastening means 370, it is preferable that the fastening means 370 include a bolt. The blade 360 is fastened to the screw hole 14 of the blade mounting portion 313 through a bolt penetrating through a state in which one end of the blade mounting portion 313 of the rotor housing 310 is located. The end of the wing 360 is fastened by a bolt and supported by the wing support protrusions 13 of the wing mounting portion 313 so that the wing 360 is coupled to the wing mounting portion 313.

7 is a flow chart showing an embodiment of a method for manufacturing an axial fan-integrated rotor according to the present invention.

As shown in Fig. 7, one embodiment of the method for manufacturing an axial fan-integrated rotor according to the present invention is, first, a bush 340 and a back yoke ring 320 are arranged inside the mold for forming the rotor housing 310 Injecting molten aluminum to form the rotor housing 310 (S1) proceeds. The rotor housing 310 has a cylindrical portion 311 in the form of a cylinder, a cover portion 312 that blocks one end of the cylindrical portion 311, and protrudes from the outer peripheral surface of the cylindrical portion 311 at regular intervals in the circumferential direction. A plurality of wing mounting portions 313 formed, an insertion hole H penetrating through the center of the cover portion 312, and a cylindrical shape on the rim of the insertion hole H located inside the cylindrical portion 311 It includes a bush coupling portion 314 that protrudes to extend, and the back yoke ring 320 is inserted into the inner peripheral surface of the cylindrical portion 311, and the bush 340 is inserted into the inner peripheral surface of the bush coupling portion 314. The cylindrical portion 311, the cover portion 312, the wing mounting portions 313, the insertion hole H, and the bush coupling portion 314 of the rotor housing 310 are the cylindrical portions 311 of the rotor housing 310 described above. ), the cover part 312, the wing mounting part 313, the insertion hole, the same as the bush coupling part 314. Balancing holes 315 are formed on the rim of the cover part 312 of the rotor housing 310 at a uniform distance from each other in the circumferential direction. The bush 340 includes an annular ring-shaped support body 341 having a set length, an annular ring groove 342 formed to have a uniform width and depth on the outer circumferential surface of the support body 341, and the annular ring groove ( It includes a rough surface portion 343 made of a plurality of fine protrusions formed on the outer circumferential surface of the support body portion 341 located between the 342 and one end of the support body portion 341. That is, the bush 340 is the same as the bush 340 described above.

After forming the rotor housing 310 in which the back yoke ring 320 and the bush 340 are inserted by insert molding, the magnet members 330 are spaced in the circumferential direction on the back yoke ring 320 of the rotor housing 310 The attaching step (S2) proceeds.

After attaching the magnet members 330, a step (S3) of pressing the rotor shaft 350 into the bush 340 of the rotor housing 310 molded by insert injection is performed.

After pressing the rotor shaft 350, a step (S4) of coupling the blades 360 to the blade mounting portions 313 of the rotor housing 310 by bolts proceeds. The blade 360 is fastened to the screw hole 14 of the blade mounting part 313 by passing through the end of the blade 360 with a bolt while one end is positioned on the blade mounting part 313 of the rotor housing 310. The end of the wing 360 is fastened by a bolt and supported by the wing support protrusions 13 so that the wing 360 is coupled to the wing mounting portion 313.

After the wing 360 is bolted to the wing mounting portion 313, a step (S5) of adjusting the rotational balancing of the rotor housing 310 is performed. Rotation balancing is performed by filling a mass body in any of the balancing holes 315 of the rotor housing 310 and balancing.

In the axial fan-integrated rotor 300 manufactured as described above, the rotor housing 310 covers the stator 200 and the bearing supporter 110 while the rotor shaft 350 is rotated by the bearings on the bearing supporter 110 Are combined.

Hereinafter, the operation and effect of the axial fan-integrated rotor and the method of manufacturing the same according to the present invention will be described.

First, in the outer rotor type motor equipped with the axial fan-integrated rotor 300, when current is applied to the winding coils of the stator 200, flux is formed in the winding coils, and the flux formed in the winding coils of the stator 200 A rotational force is generated in the magnet members 330 by the electromagnetic interaction of the flux formed by the magnet members 330 of the rotor 300 integrated with the axial fan. The rotor housing 310 and the blades 360 rotate together with the rotor shaft 350 as an axis by the rotational force of the magnet members 330. As the rotation of the blades 360 rotates, air flow is generated.

In the present invention, a plurality of wing mounting portions 313 are provided on the rotor housing 310, and the wings 360 are respectively fastened to the wing mounting portions 313 by bolts, which are fastening means 370, so that the wing 360 is attached to the rotor. The operation of coupling to the housing 310 is simple. In addition, when the blades 360 are assembled to the rotor housing 310, assembly deformation of the blades 360 due to heat is prevented, and the assembly position of the blades 360 is correct. For this reason, noise generation is minimized when the rotor housing 310 and the blades 360 rotate.

In addition, the present invention manufactures the rotor housing 310 by integrating the back yoke ring 320 and the bush 340 by insert molding, and the magnet member 330 on the rotor housing 310 manufactured by the insert molding. ), the rotor shaft 350, and the blades 360 are each combined, so manufacturing is simple, and the balance holes 315 are filled with a mass to adjust the balance, so that the balancing is accurate and the balancing operation is simple. It becomes suitable.

In addition, in the present invention, when the bush 340 is provided with an annular ring groove 342 formed to have a uniform width and depth on the outer circumferential surface and a rough surface 343 made of a plurality of fine protrusions on one side of the outer circumferential surface, the bush ( 340 is rigidly coupled to the rotor housing 310.

310; Rotor housing 320; Back York Ring
330; Magnet member 340; bush
350; Rotor shaft 360; wing

Claims (7)

A cylindrical part in the form of a cylinder, a cover part blocking one end of the cylindrical part, a plurality of wing mounting parts protruding at predetermined intervals in the circumferential direction on the outer circumferential surface of the cylindrical part, and an insertion hole formed through the center of the cover part And, a rotor housing including a bush coupling portion extending in a cylindrical shape to an edge of an insertion hole positioned inside the cylindrical portion;
A back yoke ring coupled to an inner peripheral surface of the cylindrical portion of the rotor housing;
A plurality of magnet members coupled to the back yoke ring at predetermined intervals;
A bush coupled to a bush coupling portion of the rotor housing;
A rotor shaft located inside the rotor housing and coupled to the bush;
An axial fan-integrated rotor comprising a plurality of blades respectively fastened to the blade mounting portions of the rotor housing by fastening means. The integrated axial fan according to claim 1, wherein balancing holes are provided at an edge of the cover part of the rotor housing at uniform intervals from each other in a circumferential direction, and a mass is filled in any of the balancing holes. Rotor. The mounting base plate of claim 1, wherein the blade mounting portion of the rotor housing has a longitudinal direction in a circumferential direction of the cylindrical portion, but extends so as to be inclined to a longitudinal center line of the cylindrical portion, and both ends of the mounting base plate in the longitudinal direction On the other side of the mounting base plate so as to be located between the reinforcing ribs protruding each in one direction, the wing support protrusions protruding at intervals from each other on one side of the mounting base plate, and the wing support protrusions. An axial fan-integrated rotor that extends and protrudes and includes a fastening protrusion having a screw hole therein. The method of claim 1, wherein the bush has an annular ring-shaped support body having a set length, an annular ring groove formed to have a uniform width and depth on an outer circumferential surface of the support body, and between the annular ring groove and one end of the support body. An axial fan-integrated rotor comprising a rough surface made of a plurality of fine protrusions formed on the outer circumferential surface of the support body located at. Arranging a bush and a back yoke ring in the rotor housing molding mold, and injecting molten aluminum to form the rotor housing;
Attaching magnet members to the back yoke ring of the motor housing in a circumferential direction at predetermined intervals;
Pressing the rotor shaft into the bush of the rotor housing molded by the insert injection;
Coupling the blades to the blade mounting portions of the rotor housing by bolts;
Including the step of balancing the rotation of the rotor housing,
The rotor housing includes a cylindrical portion in the form of a cylinder, a cover portion blocking one end of the cylindrical portion, a plurality of wing mounting portions protruding from the outer circumferential surface of the cylindrical portion at predetermined intervals in the circumferential direction, and penetrating in the center of the cover portion And a bush coupling portion extending in a cylindrical shape to an edge of the insertion hole positioned inside the cylindrical portion, and the back yoke ring is inserted into the inner peripheral surface of the cylindrical portion, and the back yoke ring is inserted into the inner peripheral surface of the bush coupling portion. A method of manufacturing an axial fan-integrated rotor, characterized in that a bush is inserted. 6. The axial flow according to claim 5, wherein balancing holes are formed at a circumferential direction at an rim of the cover part of the rotor housing at uniform intervals from each other, and a mass is filled in any of the balancing holes to match the balancing. How to make a fan-integrated rotor. The method of claim 5, wherein the bush has an annular ring-shaped support body having a set length, an annular ring groove formed to have a uniform width and depth on an outer circumferential surface of the support body, and between the annular ring groove and one end of the support body. A method of manufacturing an axial fan-integrated rotor comprising a rough surface made of a plurality of fine protrusions formed on the outer circumferential surface of the support body located at.

Images