KR20200145790A - Motor assembly and manufacturing method thereof - Google Patents

Abstract

According to one embodiment of the present invention, disclosed is a motor assembly comprising: a rotary shaft; an impeller installed on the rotary shaft; a rotor installed on the rotary shaft to be separated from the impeller at a predetermined interval in an axial direction of the rotary shaft; a stator surrounding the outer side of the rotor to be separated from the rotor at a predetermined interval in a radial direction of the rotary shaft; a first bearing installed on the rotary shaft to be adjacent to the impeller between the impeller and the rotor to support a first support portion of the rotary shaft; a second bearing installed on the rotary shaft to be adjacent to the rotor between the impeller and the rotor to support a second support portion of the rotary shaft; a bearing bracket accommodating the first bearing and the second bearing; an elastic member interposed between the first bearing and the bearing bracket or between the second bearing and the bearing bracket to press one of the first bearing and the second bearing in a direction in which the first bearing and the second bearing are close to each other; and a separation prevention member installed in the bearing bracket and at least partially overlapping one of the first bearing, the second bearing, and the elastic member with respect to the axial direction of the rotary shaft to fix the first bearing, the second bearing, and the elastic member to an inner space of the bearing bracket. According to the present invention, noise and vibration can be reduced by improving the alignment between two bearings.

Description

Motor assembly and its manufacturing method {MOTOR ASSEMBLY AND MANUFACTURING METHOD THEREOF}

Embodiments of the present invention relate to a motor assembly and a manufacturing method thereof, and more particularly, to a motor assembly including a bearing supporting a rotating shaft and a manufacturing method thereof.

The motor may be installed in a home appliance such as a vacuum cleaner or a hair dryer, and may function as a driving source generating rotational force. The motor may be coupled to a fan, and in this case, the rotational force of the motor may be transmitted to the fan, so that airflow may be generated according to the rotation of the fan.

Since the vacuum cleaners and hair dryers for example above are operated by the user's own hand, it is the key of recent engineering to manufacture as much lighter weight and smaller volume as possible, provided that the necessary functions are improved or at least kept the same. There is no need to increase the value.

In general, in designing and manufacturing home appliances, as well as vacuum cleaners and hair dryers, it is required to improve or at least maintain unique functions while reducing weight and miniaturization. This is to maximize the user's convenience, and is a matter that must be considered indispensable to secure differentiation from competing products in the fierce market.

As an example, in the case of a cleaner, it is required to reduce the size and weight of the motor while improving the output of the motor. For this, high-speed rotation of the motor is essential. However, the high-speed rotation of the motor inevitably causes noise and vibration problems.

Conventional motors have two bearings to support a rotating shaft that rotates at high speed, but one rolling bearing is installed in each direction around the rotor and stator (Korean Patent No. 10-1852111, 2018.03.21 Publicly available), or it was common to install one gas bearing in both directions centering on the rotor and the stator (Korean Patent No. 10-1898348, published on June 25, 2018).

In such a structure in which the two bearings support the distant parts of the rotating shaft, if the rotation center of the rotating shaft is not correctly aligned, there is a problem that not only the noise and vibration are deepened, but the life of the motor is also shortened. .

In addition, since two bearing brackets each accommodating the two bearings must be provided, the overall weight of the motor assembly increases, and at the same time, additional space to install the bearing and the bearing bracket is required, which requires miniaturization and weight reduction of the motor. The trend cannot be reflected, and as each bearing bracket is machined into different parts, the alignment between the two housings is inevitably poor due to assembly tolerances and machining tolerances.

Therefore, in order to secure the reliability and durability of the motor in response to noise and vibration problems caused by such misalignment, and to achieve a compact and lightweight motor, the rotating shaft of a high-speed motor can be supported without deformation or damage for as long as possible. The design of the bearing is essential.

Patent Document 1: Korean Patent Registration No. 10-1852111, 2018.03.21 published Patent Document 2: Korean Patent Registration No. 10-1898348, 2018.06.25 published

Embodiments of the present invention solve the provision of a motor assembly having high reliability and durability in supporting a rotating shaft of a motor rotating at high speed and a method of manufacturing the same while satisfying the requirements for miniaturization and weight reduction of a motor assembly installed in a home appliance. Make it the task you want to do.

In addition, it is an object to be solved to provide a motor assembly capable of reducing noise and vibration by improving alignment between two bearings and a method of manufacturing the same.

In addition, it is an object to be solved to provide a motor assembly capable of simplifying the structure of an overall motor assembly by reducing the number of bearing brackets for accommodating two bearings, and a manufacturing method thereof.

In addition, it is an object to be solved to provide a motor assembly capable of miniaturization and weight reduction of the motor assembly and a manufacturing method thereof while securing sufficient bearing life by expanding the size of the bearing.

A motor assembly and a manufacturing method thereof according to embodiments of the present invention for solving the above-described problems are technically characterized by eccentrically supporting a rotating shaft with two bearings, and applying an appropriate preload to the bearings.

Specifically, two bearings are accommodated in one bearing bracket, the two bearings are arranged to be spaced apart by a predetermined distance along the axial direction of the rotation shaft, and one bearing is pressed in a direction in which the two bearings are close to each other, A bearing that directly receives is attached to the bearing bracket through an adhesive, and the bearing receiving a pressing force is press-fitted to the bearing bracket to apply a preload to the bearings.

In addition, the two bearings are technically characterized in that they have an outer diameter larger than the inner diameter of the stator.

An embodiment of the present invention includes a rotating shaft, an impeller installed on the rotating shaft, a rotor installed on the rotating shaft so as to be spaced apart from the impeller by a predetermined distance along the axial direction of the rotating shaft, and the rotor so as to be spaced apart from the rotor by a predetermined distance along the radial direction of the rotating shaft. The stator surrounding the outside and a first bearing installed on the rotating shaft, installed adjacent to the impeller between the impeller and the rotor, and supporting the first support of the rotating shaft, and installed on the rotating shaft, in the rotor between the impeller and the rotor. A second bearing installed adjacent to the second supporting part of the rotating shaft, a bearing bracket accommodating the first bearing and the second bearing, and interposed between the first bearing and the bearing bracket or between the second bearing and the bearing bracket. An elastic member for pressing one of the first bearing and the second bearing in a direction in which the 1 bearing and the second bearing are close to each other, and an elastic member installed on the bearing bracket, at least partly with one of the first bearing, the second bearing, and the elastic member Disclosed is a motor assembly including a separation preventing member that overlaps each other with respect to an axial direction of a rotation shaft and fixes a first bearing, a second bearing, and an elastic member in an inner space of a bearing bracket.

In this embodiment, the separation preventing member may be characterized in that it is installed on the bearing bracket so as to surround the outer peripheral surface of the bearing bracket.

In this embodiment, the bearing bracket includes an installation groove that is depressed at a predetermined distance along the radial direction of the rotation axis from the inner circumferential surface of the bearing bracket, and the separation preventing member is in a compressed state compressed according to an external force and applied from the outside. It is characterized in that it is elastically deformable between the compressed state and the expanded normal state as it is removed by the losing force, and the separation preventing member may be installed in the installation groove in a compressed state.

In this embodiment, the separation preventing member may be characterized in that it has a diameter substantially corresponding to or smaller than the diameter of the inner peripheral surface of the bearing bracket in the compressed state.

In this embodiment, an outer diameter of the first bearing and an outer diameter of the second bearing may be larger than an inner diameter of the stator.

In this embodiment, the first bearing is interposed between the first inner ring press-fitted to the outer peripheral surface of the first support portion of the rotation shaft, the first outer ring contacting the inner surface of the bearing bracket, and the first inner ring and the first outer ring. Includes a first rolling member for supporting a relative rotational motion of the first inner ring with respect to the first outer ring, and the second bearing contacts a second inner ring that is press-fitted to the outer peripheral surface of the second support part of the rotation shaft, and the inner surface of the bearing bracket It may include a second outer ring and a second rolling member interposed between the second inner ring and the second outer ring to support a relative rotational motion of the second inner ring with respect to the second outer ring.

In this embodiment, one of the first outer ring and the second outer ring is press-fitted to the inner surface of the bearing bracket, and the other of the first outer ring and the second outer ring is fixed to the inner surface of the bearing bracket through an adhesive. You can do it.

In this embodiment, the other one of the first outer ring and the second outer ring is the inner side of the bearing bracket for a predetermined time from immediately after the other one of the first outer ring and the second outer ring is attached to the inner surface of the bearing bracket through an adhesive. It is characterized in that it is possible to slide a predetermined distance along the axial direction of the rotating shaft along the surface, and after a predetermined time elapses, the other of the first outer ring and the second outer ring is fixed to the inner surface of the bearing bracket by adhering an adhesive. I can.

In this embodiment, the elastic member presses one of the first outer ring and the second outer ring to the other side of the first outer ring and the second outer ring, and one of the first and second rolling members is the first outer ring and the second outer ring. 2 The pressing force of the elastic member is received from one of the outer rings, and the pressing force is transmitted to one of the first inner ring and the second inner ring, and the rotation shaft moves along the direction of the pressing force transmitted to one of the first and second inner rings. The other of the 1 inner ring and the second inner ring also moves together with the rotation shaft, and the other of the first and second inner rings transmits a pressing force to the other of the first and second rolling members, and the first and second rolling members The other of the two rolling members may be characterized by transmitting a pressing force transmitted from the other one of the first inner ring and the second inner ring to the other one of the first outer ring and the second outer ring.

In this embodiment, as the elastic member presses one of the first outer ring and the second outer ring to the other side of the first outer ring and the second outer ring, the first rolling member substantially contacts the first inner ring and the first outer ring. Maintaining one state, the second rolling member may be characterized in that it maintains a state in substantially contact with the second inner ring and the second outer ring.

In another embodiment of the present invention, the steps of installing the first bearing and the second bearing on the rotating shaft, inserting an elastic member into the bearing bracket, and the rotating shaft having the first bearing and the second bearing penetrate the bearing bracket. The first bearing and the second bearing are seated on the bearing bracket so that the second bearing and the elastic member are in contact with each other, and at least part of the first bearing overlaps with the first bearing based on the axial direction of the rotation shaft. A motor comprising the step of installing a prevention member to the bearing bracket, wherein the elastic member is interposed between the second bearing and the bearing bracket to press the second bearing in a direction in which the first bearing and the second bearing are close to each other. Disclosed is a method of manufacturing an assembly.

In this embodiment, the separation preventing member may be characterized in that it is installed on the bearing bracket so as to surround the outer peripheral surface of the bearing bracket.

In this embodiment, the bearing bracket includes an installation groove that is depressed at a predetermined distance along the radial direction of the rotation axis from the inner circumferential surface of the bearing bracket, and the separation preventing member is in a compressed state compressed according to an external force and applied from the outside. It is characterized in that it is elastically deformable between the compressed state and the expanded normal state as it is removed by the losing force, and the separation preventing member may be installed in the installation groove in a compressed state.

In this embodiment, the first inner ring of the first bearing may be press-fitted to the first support portion of the rotation shaft, and the second inner ring of the second bearing may be press-fitted to the second support portion of the rotation shaft.

In this embodiment, the first outer ring of the first bearing is press-fitted to the inner surface of the bearing bracket, and the second outer ring of the second bearing is fixed to the inner surface of the bearing bracket through an adhesive. .

In the present embodiment, the second outer ring of the second bearing is attached to the inner surface of the bearing bracket through an adhesive for a predetermined period of time from immediately after the elastic member presses the second outer ring toward the first outer ring. It is possible to slide a predetermined distance along the axial direction of the rotation shaft along the surface, and after a predetermined time elapses, the second outer ring may be fixed to the inner surface of the bearing bracket.

Another embodiment of the present invention is the step of installing the first bearing and the second bearing on the rotating shaft, and inserting the rotating shaft into the bearing bracket so that the rotating shaft in which the first bearing and the second bearing are installed penetrate the bearing bracket, And seating the second bearing on the bearing bracket; inserting the elastic member into the bearing bracket so that the first bearing and the elastic member contact each other; and at least a portion of the elastic member and the elastic member contacting each other based on the axial direction of the rotation shaft. Disclosed is a method of manufacturing a motor assembly comprising the step of installing a separation preventing member to a bearing bracket.

In this embodiment, the separation preventing member may be characterized in that it is installed on the bearing bracket so as to surround the outer peripheral surface of the bearing bracket.

In this embodiment, the bearing bracket includes an installation groove that is depressed at a predetermined distance along the radial direction of the rotation axis from the inner circumferential surface of the bearing bracket, and the separation preventing member is in a compressed state compressed according to an external force and applied from the outside. It is characterized in that it is elastically deformable between the compressed state and the expanded normal state as it is removed by the losing force, and the separation preventing member may be installed in the installation groove in a compressed state.

In this embodiment, the elastic member may be interposed between the first bearing and the separation preventing member to press the first bearing in a direction in which the first bearing and the second bearing are close to each other.

In this embodiment, the first inner ring of the first bearing may be press-fitted to the first support portion of the rotation shaft, and the second inner ring of the second bearing may be press-fitted to the second support portion of the rotation shaft.

In this embodiment, the first outer ring of the first bearing may be fixed to the inner surface of the bearing bracket through an adhesive, and the second outer ring of the second bearing may be press-fitted to the inner surface of the bearing bracket.

In this embodiment, the first outer ring of the first bearing is attached to the inner surface of the bearing bracket through an adhesive for a predetermined period of time from immediately after the elastic member presses the first outer ring toward the second outer ring. It is possible to slide a predetermined distance along the axial direction of the rotation shaft along the surface, and after a predetermined time elapses, the first outer ring may be fixed to the inner surface of the bearing bracket.

According to the motor assembly and its manufacturing method according to the embodiments of the present invention as described above, the rotating shaft is eccentrically supported by two bearings, but by applying an appropriate preload to the bearings, it is possible to realize miniaturization and weight reduction of the motor assembly. Noise and vibration can be reduced by improving the alignment between the two bearings.

In addition, according to the motor assembly and manufacturing method according to the embodiments of the present invention as described above, two bearings are accommodated in one bearing bracket, but the two bearings are arranged to be spaced apart by a predetermined distance along the axial direction of the rotation shaft. It is possible to simplify the structure of the overall motor assembly, and at the same time, it is possible to stably support the rotating shaft, thereby ensuring the reliability and durability of the bearing structure.

In addition, according to the motor assembly and manufacturing method according to the embodiments of the present invention as described above, the two bearings for eccentrically supporting the rotating shaft have an outer diameter larger than the inner diameter of the stator, thereby increasing the size of the bearing to increase the sufficient bearing life. Can be secured.

Embodiments of the present invention can be easily understood by the following detailed description and a combination of the accompanying drawings, and reference numerals denote structural elements.
1 is a cross-sectional view showing each configuration of a motor assembly according to an embodiment of the present invention.
FIG. 2 is an exploded perspective view showing a part of the motor assembly shown in FIG. 1 by exploding.
3 is an enlarged cross-sectional view showing an enlarged portion A of FIG. 1.
4 is an enlarged cross-sectional view showing a modified example of FIG. 3.
5 is an enlarged cross-sectional view showing another modified example of FIG. 3.
6 is a conceptual diagram showing a comparison of a normal state and a compressed state of the separation preventing member shown in FIG. 5.
7 is an exploded cut-away perspective view showing the motor assembly shown in FIG.
8 is an enlarged cross-sectional view showing a modified example of FIG. 7.
9 is a conceptual diagram specifically showing a relationship between a force exerted on a rotation shaft, a first bearing, and a second bearing by the elastic member shown in FIGS. 3 and 5.
10 is a conceptual diagram specifically showing a relationship between a force exerted on a rotation shaft and a first bearing and a second bearing by the elastic member shown in FIGS. 4 and 8.
11 is a flowchart schematically showing a method of manufacturing the motor assembly shown in FIGS. 3 and 5.
12 to 16 are conceptual diagrams sequentially showing a method of manufacturing the motor assembly shown in FIG. 11.
17 is a flowchart schematically illustrating a method of manufacturing the motor assembly shown in FIGS. 4 and 8.
18 to 22 are conceptual diagrams sequentially illustrating a method of manufacturing the motor assembly shown in FIG. 17.

The terms used in the present specification have selected general terms that are currently widely used as possible while taking the functions of the embodiments of the present invention into consideration, but this may vary according to the intention or precedent of a person skilled in the art, the emergence of new technologies, and the like. In addition, in certain cases, there are terms arbitrarily selected by the applicant, and in this case, the meaning of the terms will be described in detail in the description of the corresponding invention. Therefore, the terms used in the present specification should be defined based on the meaning of the term and the contents throughout the specification, not a simple name of the term.

In addition, when a certain part "includes" a certain component throughout the specification, this means that other components may be further included rather than excluding other components unless otherwise stated.

In addition, regardless of the reference numerals, identical or corresponding components are given the same reference numbers, and duplicate descriptions thereof will be omitted, and the size and shape of each component member shown for convenience of explanation may be exaggerated or reduced. have.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art to which the embodiments of the present invention belong can easily implement. However, embodiments of the present invention may be implemented in various different forms and are not limited to the embodiments described herein.

1 is a cross-sectional view showing each configuration of a motor assembly according to an embodiment of the present invention, FIG. 2 is an exploded perspective view showing a part of the motor assembly shown in FIG. 1, and FIG. 3 is a It is an enlarged cross-sectional view showing an enlarged portion.

1 to 3, the motor assembly 100 includes an inlet body 51, a motor housing 52, a supporter 53, a diffuser 54, a rotating shaft 110, an impeller 120, and a rotor 130. , A stator 140, a first bearing 150, a second bearing 160, a bearing bracket 170, an elastic member 180, and a separation preventing member 190. Here, the inlet body 51 and the motor housing 52 form the exterior of the motor assembly 100, and all other components may be accommodated in an empty space provided therein.

Specifically, the inner space of the motor assembly 100 is an impeller space S1, which is an empty space provided inside the inlet body 51, and a motor space S2, which is an empty space provided inside the motor housing 52. Can be distinguished. The gas flowing through the impeller space S1 and the motor space S2 can cool each component provided in the motor assembly 100, thereby reducing heat generation of the motor assembly 100. .

The inlet body 51 may include a suction port 511 through which gas is sucked, and may be disposed to surround the outer circumference of the impeller 120. That is, an impeller space S1 in which the impeller 120 is rotatably accommodated may be formed inside the inlet body 51, and the appearance thereof corresponds to the shape of the impeller 120, while the impeller space S1 The inner surface may be formed to be curved so as to stably guide the gas flowing along the line. One side 110A of the rotation shaft 110 may be accommodated in the impeller space S1.

Hereinafter, a part of the rotation shaft 110 accommodated in the inlet body 51 is defined as one side 110A of the rotation shaft 110, and another part of the rotation shaft 110 accommodated in the motor housing 52 is defined as the other side 110B. ).

Specifically, the opposite side of the suction port 511 of the inlet body 51 may be coupled to the motor housing 52 to form the exterior of the motor assembly 100. The fastening portions of the inlet body 51 and the motor housing 52 may be fastened so that the gas flowing inside the motor assembly 100 does not flow out through a space other than the outlet 521 to the outside.

That is, it is preferable to securely fasten each other so that no gap is formed between the inlet body 51 and the motor housing 52, and various methods such as screwing or fitting may be used as the fastening method. It is not limited to any particular method.

In other words, the inlet body 51 and the motor housing 52 may be a kind of hollow case, and may be disposed so that the rotation shaft 110 extends in the axial direction in an empty space in the center. As shown in the drawing, the rotation shaft 110 may not be directly supported by the inlet body 51 or the motor housing 52. That is, the inlet body 51 or the motor housing 52 may not be provided with a separate rotation shaft supporter (tentative name) for supporting the rotation shaft 110.

The motor housing 52 is formed so as to surround the outer circumference of the stator 140, the stator 140 is installed on the inner circumferential surface, and is fastened to the inlet body 51 to form the exterior of the motor assembly 100. In detail, a motor space S2 in which the other side 110B of the rotation shaft 110 and the rotor 130 and the stator 140 can be accommodated may be formed in the motor housing 52.

In addition, the motor housing 52 may include an outlet 521 through which gas guided from the impeller space S1 to the motor space S2 is discharged to the outside of the motor housing 52 by rotation of the impeller 120. In addition, the outlet 521 may be formed on the opposite side of the suction port 511 based on the flow direction of the gas.

The supporter 53 supports the bearing bracket 170 to be described later, and may be fastened to the motor housing 52. Specifically, in the supporter 53, a through hole (not shown) through which the rotation shaft 110 passes is perforated in the center, and a bearing bracket 170 is inserted into the through hole to be installed.

The diffuser 54 may be fastened with the supporter 53, and is disposed between the supporter 53 and the impeller 120 to guide the gas flowing into the inlet body 51 toward the motor housing 52. have. That is, a predetermined space through which gas can flow may be formed between the diffuser 54 and the inlet body 51. The diffuser 54 may be fastened and fixed to the supporter 53 through fastening members (not shown) such as bolts and nuts.

Specifically, a plurality of diffuser vanes 541 protruding toward the inner surface of the inlet body 51 may be formed on the outer surface of the diffuser 54. The plurality of diffuser vanes 541 may convert the dynamic pressure of the gas passing through the impeller 120 into a positive pressure.

The plurality of diffuser vanes 541 may be disposed to be spaced apart from each other by substantially the same distance along the circumferential direction from the outer peripheral surface of the diffuser 54, but embodiments are not limited thereto. For example, the distance between the plurality of diffuser vanes 541 may gradually increase and decrease, may decrease and then increase, and may even be formed differently. In addition, the diffuser 54 may further include a through hole (not shown) through which the supporter 53 and the rotation shaft 110 pass.

According to this structure, gas flowing into the inlet body 51 through the inlet 511 may be guided by the impeller 120 to the space between the inlet body 51 and the diffuser 54, and the inlet body The gas flowing between the 51 and the diffuser 54 may be guided from the impeller space S1 to the motor space S2 by a plurality of diffuser vanes 541.

Meanwhile, the diffuser 54 may be formed integrally with the supporter 53, but preferably may be manufactured separately from the supporter 53 and then fastened to the supporter 53. When the supporter 53 and the diffuser 54 are integrally formed, the assembly tolerance can be relatively reduced, and accordingly, the flow of gas flowing into the inlet body 51 can be facilitated.

The rotation shaft 110 may be extended to cross the impeller space S1 and the motor space S2. In other words, the rotation shaft 110 may be formed to extend in the longitudinal direction of the motor assembly 100, that is, in the axial direction.

Specifically, the rotation shaft 110 may be accommodated in the inlet body 51 and the motor housing 52. That is, a part of the rotation shaft 110 may be accommodated in the inlet body 51 and another part may be accommodated in the motor housing 52 along the longitudinal direction. In addition, a part of the rotation shaft 110 accommodated in the inlet body 51 may be accommodated in a bearing bracket 170 to be described later.

In other words, one side 110A of the rotation shaft 110 may be disposed on the inlet body 51 and the bearing bracket 170 side, and the other side 110B of the rotation shaft 110 is on the motor housing 52 side. Can be placed.

One end (110C) of the rotation shaft 110 may be a free end that is not supported by the inlet body 51 or the bearing bracket 170, and the other end (110D) of the rotation shaft 110 is also not supported by the motor housing 52. It can be a free group that does not. Here, the "free end" may mean both ends of the rotating shaft 110 that are not supported or restricted by any of the components.

One end 110C of the rotation shaft 110 may be disposed adjacent to the impeller 120 among the impeller 120 and the rotor 130, and may be a free end of the impeller 120 side. In addition, the other end 110D of the rotation shaft 110 may be disposed adjacent to the rotor 130 among the impeller 120 and the rotor 130, and may be a free end on the rotor 130 side.

Meanwhile, as will be described later, the rotation shaft 110 may be supported by a plurality of bearings between one end 110C and the other end 110D. Here, the plurality of bearings may mean a first bearing 150 and a second bearing 160 to be described later, and these will be described in detail below.

On the other hand, the rotating shaft 110 is a second impeller coupling portion 111 on which the impeller 120 is installed, a first support portion 112 on which the first bearing 150 is installed, and a second bearing 160 on which the second bearing 160 is installed. It may include a supporting part 113 and a rotor coupling part 114 on which the rotor 130 is installed.

The impeller coupling part 111 is a part of the rotation shaft 110 on which the impeller 120 is installed, and is a part adjacent to one end 110C among the one side 110A of the rotation shaft 110, and is disposed in the impeller space S1. It may be disposed adjacent to the inlet 511 of the inlet body 51 through which gas is introduced from the outside.

The first support part 112 is a part of the rotation shaft 110 on which the first bearing 150 to be described later is installed, and is a part corresponding to one side 110A of the rotation shaft 110, and may be disposed in the impeller space S1. . That is, the first support part 112 is a part of the rotation shaft 110 overlapping with the first bearing 150 along the radial direction of the rotation shaft 110, and is supported in the radial and axial directions by the first bearing 150 Can be.

The second support part 113 is a part of the rotation shaft 110 on which the second bearing 160 to be described later is installed, and is a part corresponding to one side 110A of the rotation shaft 110, and may be disposed in the impeller space S1. . That is, the second support part 113 is a part of the rotation shaft 110 overlapping the second bearing 160 along the radial direction of the rotation shaft 110, and is supported in the radial and axial directions by the second bearing 160 Can be.

In addition, the first support 112 and the second support 113 are both portions corresponding to one side (110A) of the rotation shaft 110, the first support 112 is the impeller 120 than the second support 113 The second support part 113 may be closer to the side, and the second support part 113 may be closer to the rotor 130 side than the first support part 112.

The rotor coupling part 114 is a part of the rotation shaft 110 in which the rotor 130 is installed, and is a part adjacent to the other end 110D among the other side 110B of the rotation shaft 110, and is disposed in the motor space S2. I can. That is, the rotor coupling part 114 may be a part of the rotation shaft 110 overlapping the rotor 130 along the radial direction of the rotation shaft 110.

The rotation shaft 110 can be rotated by an electromagnetic interaction between the rotor 130 and the stator 140, and as the rotation shaft 110 rotates, the impeller 120 fastened to the rotation shaft 110 and the rotation shaft 110 It may rotate together with, and gas may be sucked into the motor assembly 100 according to the rotation of the impeller 120.

Impeller 120 may be installed on one side (110A) of the rotation shaft (110). That is, the impeller 120 may be installed on the opposite side of the other side 110B of the rotation shaft 110 on which the rotor 130 is installed based on the axial direction of the rotation shaft 110. As described above, the impeller 120 is fastened to the impeller coupling portion 111 of the rotation shaft 110 and can rotate together with the rotation of the rotation shaft 110, and the impeller space provided inside the inlet body 51 It can be placed in (S1).

Specifically, the impeller 120 may include a hub 121 and a plurality of blades 122 formed to protrude outward from the outer circumference of the hub 121. Meanwhile, the impeller 120 may be formed of a high-strength synthetic resin material such as polyetheretherketone (PEEK) as a material thereof. However, the material of the impeller 120 is not limited thereto, and may be made of metal as well as other high-strength synthetic resins.

In addition, the impeller 120 may be a four-flow impeller that sucks gas such as air in the axial direction of the rotation shaft 110 and discharges it in an oblique direction between the centrifugal direction and the axial direction. That is, the gas flowing into the inlet body 51 through the inlet 511 may be guided toward the motor housing 52 along the outer surface of the hub 121 according to the rotation of the blade 122.

However, embodiments of the present invention are not limited thereto, and the impeller 120 may be configured as a centrifugal impeller that sucks gas in the axial direction and discharges it in the centrifugal direction. However, hereinafter, for convenience of explanation, the impeller 120 will be described mainly in the case of a four-flow type impeller.

The rotor 130 may be installed on the other side 110B of the rotation shaft 110. In other words, the rotor 130 may be installed on the rotor coupling portion 114 located on the other side 110B of the rotation shaft 110. That is, the rotor 130 may be coupled to the rotation shaft 110 so as to surround the outer circumferential surface of the rotation shaft 110, and may be disposed in the motor space S2 where the rotor coupling portion 114 is located.

Specifically, the rotor 130 may include a magnet 131 and a magnet core (not shown) on which the magnet 131 is mounted. In addition, the rotor 130 may further include a first end plate 132 and a second end plate 133 disposed to be spaced apart from each other at a predetermined interval around the magnet 131 along the axial direction of the rotation shaft 110. .

The first end plate 132 and the second end plate 133 may be installed on the rotation shaft 110 so as to surround the rotation shaft 110, and the magnet 131 and the magnet core are based on the axial direction of the rotation shaft 110. By supporting both ends of the magnet 131 and the magnet core can be firmly fixed to the rotation shaft 110 so as not to move along the axial direction.

The stator 140 may be installed on the inner circumferential surface of the motor housing 52 and surround the outer side of the rotor 130 so as to be spaced apart from the rotor 130 along a radial direction of the rotation shaft 110. That is, the stator 140 may be disposed in the motor space S2 where the rotor coupling portion 114 of the rotation shaft 110 is located, like the rotor 130.

Specifically, the stator 140 is a stator core 141 composed of a conductor, a coil 142 wound around the stator core 141, and an insulator electrically insulating between the stator core 141 and the coil 142 (143) may be included. Current may be applied to the coil 142, and as the current is applied to the coil 142, the rotor 130 may rotate with respect to the stator 140.

The first bearing 150 is installed on one side (110A) of the rotating shaft 110 to support the rotation of the rotating shaft 110, but is installed adjacent to the impeller 120 between the impeller 120 and the rotor 130 The first support part 112 of the rotation shaft 110 may be supported. In addition, the first bearing 150 may be accommodated in an empty space provided inside the bearing bracket 170.

Specifically, the first bearing 150 includes a first inner ring 151 that is press-fitted to the outer circumferential surface of the first support part 112 of the rotation shaft 110 and a first outer ring in contact with the inner surface of the bearing bracket 170 ( 152), and a first rolling member 153 interposed between the first inner ring 151 and the first outer ring 152 to support the relative rotational motion of the first inner ring 151 with respect to the first outer ring 152 It may include.

The second bearing 160, like the first bearing 150, is installed on one side (110A) of the rotation shaft 110 to support the rotation of the rotation shaft 110, but between the impeller 120 and the rotor 130 It is installed so as to be adjacent to 130 to support the second support part 113 of the rotation shaft 110. In addition, the second bearing 160 may be accommodated in an empty space provided inside the bearing bracket 170 together with the first bearing 150.

Specifically, the second bearing 160 includes a second inner ring 161 that is press-fitted to the outer circumferential surface of the second support part 113 of the rotation shaft 110 and a second outer ring in contact with the inner surface of the bearing bracket 170 ( 162), and a second rolling member 163 interposed between the second inner ring 161 and the second outer ring 162 to support a relative rotational motion of the second inner ring 161 with respect to the second outer ring 162 It may include.

Specifically, one of the first outer ring 152 and the second outer ring 162 may be press-fitted to the inner surface of the bearing bracket 170, and the other one of the first outer ring 152 and the second outer ring 162 May be fixed to the inner surface of the bearing bracket 170 through an adhesive.

That is, the method of fixing the first outer ring 152 and the second outer ring 162 to the inner surface of the bearing bracket 170 may be different. Which of the first outer ring 152 and the second outer ring 162 is to be press-fitted to the inner surface of the bearing bracket 170 or fixed through an adhesive, the elastic member 180, which will be described later, includes the first outer ring 152 and the second outer ring. It may be determined depending on which of the outer rings 162 is pressed.

That is, the side of the first outer ring 152 and the second outer ring 162 that the elastic member 180 presses is fixed to the inner surface of the bearing bracket 170 through an adhesive, and the elastic member 180 does not pressurize. The side may be press-fitted to the inner surface of the bearing bracket 170.

For example, in a state in which the elastic member 180 is pressing the second outer ring 162 as shown in FIGS. 1 to 3, the first outer ring 152 may be press-fitted to the inner surface of the bearing bracket 170. In addition, the second outer ring 162 may be fixed to the inner surface of the bearing bracket 170 through an adhesive.

In addition, the other one of the first outer ring 152 and the second outer ring 162, that is, the first outer ring 152 or the second outer ring 162 fixed to the inner surface of the bearing bracket 170 through adhesive From immediately after the other one of the outer ring 152 and the second outer ring 162 is attached to the inner surface of the bearing bracket 170 through an adhesive, the rotation shaft 110 is formed along the inner surface of the bearing bracket 170 for a predetermined time. It may be possible to slide a predetermined distance along the axial direction.

Then, after a predetermined time has elapsed, the other one of the first outer ring 152 and the second outer ring 162 may be fixed to the inner surface of the bearing bracket 170 by adhering the adhesive.

For example, referring to FIGS. 1 to 3, in the case of the second outer ring 162 fixed to the inner surface of the bearing bracket 170 through an adhesive, immediately after being attached to the inner surface of the bearing bracket 170 through the adhesive During a predetermined time, it is possible to move a predetermined distance along the axial direction of the rotation shaft 110 along the inner surface of the bearing bracket 170. Then, after a predetermined time has elapsed, the second outer ring 162 may be fixed to the inner surface of the bearing bracket 170 as the adhesive is fixed.

The reason why the second outer ring 162 can slide along the inner surface of the bearing bracket 170 before the adhesive is fixed is because the elastic member 180 moves the second outer ring 162 toward the first outer ring 152. Because of the pressure, it will be described later, but the first bearing 150 and the second bearing 160 can be preloaded through the pressing force of the elastic member 180, through which the first bearing 150 and the second bearing 160 The degree of alignment of can be improved. The relationship between the force of the first outer ring 152, the second outer ring 162, and the elastic member 180 will be described in more detail below with reference to FIGS. 9 and 10.

On the other hand, the two bearings 150 and 160 eccentrically supporting the rotating shaft 110 have an outer diameter D greater than the inner diameter 140d of the stator 140, thereby increasing the size of the bearing to secure sufficient bearing life. I can.

This is possible because according to embodiments of the present invention, it is possible to stably support the rotation shaft 110 without supporting the other side 110B of the rotation shaft 110 with a bearing, as well as improve alignment between the bearings. As a design consideration, expanding the outer diameter D of the first bearing 150 and the second bearing 160 means that the life of the bearing structure can be sufficiently secured.

The bearing bracket 170 may be installed on the supporter 53 to accommodate the first bearing 150 and the second bearing 160 in an empty space therein. In addition, the bearing bracket 170 may include a stepped step 171 overlapping the second outer ring 162 of the second bearing 160 based on the axial direction of the rotation shaft 110.

The stepped 171 may support the second outer ring 162 with an elastic member 180 to be described later interposed in the middle, and the second outer ring 162 and the elastic member 180 are separated toward the rotor 130 It is possible to prevent the second outer ring 162 and the elastic member 180 from moving toward the rotor 130.

In the bearing bracket 170, a side opposite to the stepped jaw 171, that is, a side facing the impeller 120, may be opened without a member such as the stepped 171. This is to secure a space for the first bearing 150 and the second bearing 160 to be inserted into the bearing bracket 170, which will be described later, but the first bearing 150 and the second bearing 160 After being inserted into the inner space of the bearing bracket 170, the separation preventing member 190 is installed on the bearing bracket 170 so that the first bearing 150 and the second bearing 160 do not deviate toward the impeller 120. It is possible to prevent movement of the first bearing 150 and the second bearing 160 toward the impeller 120 side.

In this way, by accommodating the two bearings 150 and 160 in one bearing bracket 170, the two bearings 150 and 160 are arranged to be spaced apart by a predetermined distance along the axial direction of the rotation shaft 110, Since only one bearing bracket 170 needs to be used to accommodate the bearings 150 and 160, the overall structure of the motor assembly 100 can be simplified, and the rotating shaft 110 stably with two bearings 150 and 160 at the same time. ) Can be supported, ensuring the reliability and durability of the bearing structure.

The elastic member 180 is interposed between the first bearing 150 and the bearing bracket 170 or between the second bearing 160 and the bearing bracket 170 to form the first bearing 150 and the second bearing 160. One of the first bearing 150 and the second bearing 160 may be pressurized in a direction approaching each other.

1 to 3, the elastic member 180 may be interposed between the second bearing 160 and the bearing bracket 170 to press the second bearing 160 toward the first bearing 150.

Specifically, the elastic member 180 may press the second outer ring 162 of the second bearing 160 toward the first outer ring 152 of the first bearing 150. The relationship between the force generated between the first bearing 150 and the second bearing 160 and the elastic member 180 will be described in more detail below with reference to FIGS. 9 and 10.

The separation preventing member 190 is installed on the bearing bracket 170, at least partially based on the axial direction of the rotation shaft 110 and one of the first bearing 150 and the second bearing 160 and the elastic member 180 By overlapping each other, the first bearing 150, the second bearing 160, and the elastic member 180 may be fixed to the inner space of the bearing bracket 170.

Specifically, at least part of the separation preventing member 190 includes the first outer ring 152 of the first bearing 150, the second outer ring 162 of the second bearing 160, or the elastic member 180 The first outer ring 152, the second outer ring 162, or the elastic member 180 so that the first outer ring 152, the second outer ring 162, or the elastic member 180 cannot be separated from the bearing bracket 170 by contacting. It is possible to prevent the movement toward the impeller 120 side or the movement toward the rotor 130 side.

1 to 3, the separation preventing member 190 may be a type of cover installed on the bearing bracket 170 so as to surround the outer circumferential surface of the bearing bracket 170. The separation preventing member 190 overlaps each other with respect to the first outer ring 152 of the first bearing 150 in the axial direction, and contacts the first outer ring 152 so that the impeller 120 of the first outer ring 152 It can prevent movement to the side.

4 is an enlarged cross-sectional view showing a modified example of FIG. 3.

Referring to FIG. 4, the elastic member 180 ′ may be interposed between the separation preventing member 190 and the first outer ring 152. That is, the elastic member 180 ′ may be interposed between the first bearing 150 and the separation preventing member 190 to press the first bearing 150 toward the second bearing 160.

Specifically, the elastic member 180 ′ may press the first outer ring 152 of the first bearing 150 toward the second outer ring 162 of the second bearing 160. The relationship between the force generated between the first bearing 150 and the second bearing 160 and the elastic member 180 ′ will be described in more detail below with reference to FIGS. 9 and 10.

Meanwhile, as shown in FIG. 4, in a state in which the elastic member 180 ′ is pressing the first outer ring 152, the second outer ring 162 may be press-fitted to the inner surface of the bearing bracket 170, and , The first outer ring 152 may be fixed to the inner surface of the bearing bracket 170 through an adhesive.

In addition, in the case of the first outer ring 152 that is fixed to the inner surface of the bearing bracket 170 through an adhesive, the bearing bracket 170 is attached to the inner surface of the bearing bracket 170 through the adhesive for a predetermined period of time. It is possible to move a predetermined distance along the axial direction of the rotation shaft 110 along the inner surface of the. And, after a predetermined time has elapsed, the first outer ring 152 may be fixed to the inner surface of the bearing bracket 170 as the adhesive is fixed.

The reason why the first outer ring 152 can slide along the inner surface of the bearing bracket 170 before the adhesive is fixed is that the elastic member 180 ′ replaces the first outer ring 152 with the second outer ring 162 Because it is pressed to the side, but will be described later, the first bearing 150 and the second bearing 160 can be preloaded through the pressing force of the elastic member 180 ′, through which the first bearing 150 and the second bearing ( 160) can be improved. The relationship between the force of the first outer ring 152, the second outer ring 162, and the elastic member 180 will be described in more detail below with reference to FIGS. 9 and 10.

5 is an enlarged cross-sectional view showing another modified example of FIG. 3, FIG. 6 is a conceptual diagram showing a comparison of a normal state and a compressed state of the separation preventing member illustrated in FIG. 5, and FIG. 7 is a motor assembly illustrated in FIG. 5. It is an exploded cutaway perspective view showing the disassembled and partially cut away.

5 to 7, the bearing bracket 270 includes an installation groove 272 recessed at a predetermined distance along the radial direction of the rotation shaft 110 from the inner circumferential surface of the bearing bracket 270, and the installation groove 272 ), a departure preventing member 290 may be installed.

The separation preventing member 290 shown in FIGS. 5 and 7 overlaps each other with respect to the first outer ring 152 of the first bearing 150 and the axial direction, and contacts the first outer ring 152 to form a first outer ring. It is possible to prevent the movement of 152 toward the impeller 120 side.

The separation preventing member 290 may be a type of snap ring that can be installed in the installation groove 272 in a compressed state. Specifically, referring to FIG. 6, the separation preventing member 290 is in a compressed state (290C) compressed according to an external force and a normal state (inflated) in a compressed state (290C) as the force applied from the outside is removed ( 290S) may be elastically deformable (D1>D2).

That is, referring to FIGS. 5 and 6 together, the separation preventing member 290 may have a diameter substantially corresponding to or smaller than the diameter of the inner circumferential surface of the bearing bracket 270 in the compressed state 290C (D2270d). According to this structure, the separation preventing member 290 enters the inner space of the bearing bracket 270 in a compressed state (290C) and returns to the normal state (290S) from the installation groove 272, and the installation groove 272 Can be fixed to

5, in a state in which the elastic member 180 presses the second outer ring 162, the first outer ring 152 may be press-fitted to the inner surface of the bearing bracket 270, and the second The outer ring 162 may be fixed to the inner surface of the bearing bracket 270 through an adhesive.

In the case of the second outer ring 162 fixed to the inner surface of the bearing bracket 270 through an adhesive, the inner side of the bearing bracket 270 for a predetermined time from immediately after being attached to the inner surface of the bearing bracket 270 through the adhesive It is possible to move a predetermined distance along the axial direction of the rotation shaft 110 along the surface. And, after a predetermined time has elapsed, the second outer ring 162 may be fixed to the inner surface of the bearing bracket 270 as the adhesive is fixed.

The reason why the second outer ring 162 can slide along the inner surface of the bearing bracket 270 before the adhesive is fixed is because the elastic member 180 moves the second outer ring 162 toward the first outer ring 152. Because of the pressure, it will be described later, but the first bearing 150 and the second bearing 160 can be preloaded through the pressing force of the elastic member 180, through which the first bearing 150 and the second bearing 160 The degree of alignment of can be improved. The relationship between the force of the first outer ring 152, the second outer ring 162, and the elastic member 180 will be described in more detail below with reference to FIGS. 9 and 10.

8 is an enlarged cross-sectional view showing a modified example of FIG. 7.

Referring to FIG. 8, the elastic member 180 ′ may be interposed between the separation preventing member 290 and the first outer ring 152. That is, the elastic member 180 ′ may be interposed between the first bearing 150 and the separation preventing member 290 to press the first bearing 150 toward the second bearing 160.

Specifically, the elastic member 180 ′ may press the first outer ring 152 of the first bearing 150 toward the first outer ring 162 of the second bearing 160. The relationship between the force generated between the first bearing 150 and the second bearing 160 and the elastic member 180 ′ will be described in more detail below with reference to FIGS. 9 and 10.

Meanwhile, as shown in FIG. 8, in a state in which the elastic member 180 ′ is pressing the first outer ring 152, the second outer ring 162 may be press-fitted to the inner surface of the bearing bracket 270, and , The first outer ring 152 may be fixed to the inner surface of the bearing bracket 270 through an adhesive.

In addition, in the case of the first outer ring 152 that is fixed to the inner surface of the bearing bracket 270 through an adhesive, the bearing bracket 270 is attached to the inner surface of the bearing bracket 270 through the adhesive for a predetermined period of time immediately after being attached to the bearing bracket 270 It is possible to move a predetermined distance along the axial direction of the rotation shaft 110 along the inner surface of the. And, after a predetermined time has elapsed, the first outer ring 152 may be fixed to the inner surface of the bearing bracket 270 as the adhesive is fixed.

The reason why the first outer ring 152 can slide along the inner surface of the bearing bracket 270 before the adhesive is fixed is that the elastic member 180 ′ replaces the first outer ring 152 with the second outer ring 162 Because it is pressed to the side, but will be described later, the first bearing 150 and the second bearing 160 can be preloaded through the pressing force of the elastic member 180 ′, through which the first bearing 150 and the second bearing ( 160) can be improved. The relationship between the force of the first outer ring 152, the second outer ring 162, and the elastic member 180 ′ will be described in more detail below with reference to FIGS. 9 and 10.

9 is a conceptual diagram specifically showing the relationship between the force exerted on the rotation shaft and the first bearing and the second bearing by the elastic member shown in Figs. 3 and 5, and Fig. 10 is a rotation shaft of the elastic member shown in Figs. It is a conceptual diagram specifically showing the relationship between the force applied to the first bearing and the second bearing.

Reference numerals 110, 150, 160, 170, 180 and 190 shown in FIGS. 9 and 10 denote a rotation shaft 110 and a first bearing 150, a second bearing 160, a bearing bracket 170, and an elastic member, respectively. 180 and the departure preventing member 190 are conceptualized and shown, which are somewhat different from the specific shape or size of each component described in FIGS. 1 to 8 above, but the unique characteristics or mutual coupling relationship of each component It should be noted in advance that the contents are the same as the above.

That is, the description of each of the components shown in FIGS. 9 and 10 is for explaining the relationship of the force between the rotation shaft 110 and the first bearing 150, the second bearing 160 and the elastic member 180 , The shapes or sizes of the components shown in FIGS. 9 and 10 do not limit the structure or coupling relationship of the embodiments.

9 depicts a case where the elastic member 180 presses the second outer ring 162 of the second bearing 160 toward the first outer ring 152 of the first bearing 150 (ie, in the first direction). . Referring to FIG. 9, the elastic member 180 presses the second outer ring 162 toward the first outer ring 152 (①), and the second rolling member 163 is formed from the second outer ring 162. 180) receives the pressing force (②) and transmits the pressing force to the second inner ring 161 (③), and the rotation shaft 110 moves along the direction of the pressing force transmitted to the second inner ring 161, that is, the first direction. However (④), the first inner ring 151 also moves in the first direction together with the rotation shaft 110 (⑤), and the first inner ring 151 transmits a pressing force to the first rolling member 153 (⑥) , The first rolling member 153 may transmit (⑦) the pressing force received from the first inner ring 151 to the first outer ring 152.

As the elastic member 180 presses the second outer ring 162 toward the first outer ring 152, the first rolling member 153 substantially contacts the first inner ring 151 and the first outer ring 152. One state can be maintained, and the second rolling member 163 can also maintain a state in substantially contact with the second inner ring 161 and the second outer ring 162 (refer to the right figure of FIG. 9).

In addition, FIG. 10 is a case in which the elastic member 180 ′ presses the first outer ring 152 of the first bearing 150 toward the second outer ring 162 of the second bearing 160 (ie, in the second direction) Describe. Referring to FIG. 10, the elastic member 180' presses the first outer ring 152 toward the second outer ring 162 (①'), and the first rolling member 153 is elastic from the first outer ring 152. It receives the pressing force of the member 180' (②') and transmits the pressing force to the first inner ring 151 (③'), and the rotation axis along the direction of the pressing force transmitted to the first inner ring 151, that is, the second direction Although (110) moves (④'), the second inner ring 161 also moves in the second direction together with the rotation shaft 110 (⑤'), and the second inner ring 161 is attached to the second rolling member 163. The pressing force is transmitted (⑥'), and the second rolling member 163 may transmit the pressing force received from the second inner ring 161 to the second outer ring 162 (⑦').

As the elastic member 180 ′ presses the first outer ring 152 toward the second outer ring 162, the first rolling member 153 substantially moves with the first inner ring 151 and the first outer ring 152. The contacted state may be maintained, and the second rolling member 163 may also maintain a state in substantially contact with the second inner ring 161 and the second outer ring 162 (refer to the right figure of FIG. 10 ).

In this way, the rotation shaft is eccentrically supported by the two bearings 150 and 160 (that is, since the other side 110B of the rotation shaft 110 is not supported by a bearing, a separate bearing structure is not required), but the elastic member 180, 180') to apply an appropriate preload to the bearings 150, 160, thereby realizing the miniaturization and weight reduction of the motor assembly 100, while improving the alignment between the two bearings 150, 160 to improve noise and vibration. Can be reduced.

11 is a flowchart schematically illustrating a method of manufacturing the motor assembly illustrated in FIGS. 3 and 5, and FIGS. 12 to 16 are conceptual diagrams sequentially illustrating a method of manufacturing the motor assembly illustrated in FIG. 11.

Referring to FIG. 11, the method of manufacturing the motor assembly 100 shown in FIGS. 3 and 5 is the step of installing the first bearing 150 and the second bearing 160 on the rotating shaft 110 (S501). And, the step of inserting the elastic member 180 into the bearing brackets 170 and 270 (S503), and the rotation shaft 110 so that the second bearing 160 and the elastic member 180 contact each other, the bearing bracket 170, Inserting into the 270 (S505), and installing the separation preventing members 190 and 290 on the bearing brackets 170 and 270 so that the first bearing 150 and the separation preventing members 190 and 290 contact each other. (S507) may be included.

After the separation preventing members 190 and 290 are installed on the bearing brackets 170 and 270, the elastic member 180 is interposed between the second bearing 160 and the bearing brackets 170 and 270 to provide the first bearing 150. The second bearing 160 may be pressed in a direction in which the and the second bearing 160 are close to each other.

Referring to FIGS. 11 and 12 together, the first inner ring 151 of the first bearing 150 may be press-fitted to the first support part 112 of the rotation shaft 110, and the second bearing 160 2 The inner ring 161 may be press-fitted to the second support part 113 of the rotation shaft 110 (S501).

As described above, the first support part 112 and the second support part 113 are located on one side 110A of the rotation shaft 110, but may be spaced apart from each other by a predetermined distance along the axial direction of the rotation shaft 110. Accordingly, the first bearing 150 and the second bearing 160 may also be installed on one side 110A of the rotation shaft 110, and may be disposed to be spaced apart from each other by a predetermined distance along the axial direction of the rotation shaft 110. .

11 and 13, before the rotation shaft 110, the first bearing 150, and the second bearing 160 are inserted and installed in the bearing bracket 170, the bearing bracket 170 has an elastic member ( 180) may be inserted (S503). In this case, the elastic member 180 may be inserted into the inner space of the bearing bracket 170 so as to be caught on the stepped jaw 171 of the bearing bracket 170.

11 and 14 together, in a state in which the elastic member 180 is inserted and installed in the inner space of the bearing bracket 170, the rotation shaft 110 in which the first bearing 150 and the second bearing 160 are installed is The second bearing 160 may be inserted through the bearing bracket 170 to make contact with the elastic member 180 (S505).

Here, the first outer ring 152 of the first bearing 150 may be press-fitted to the inner surface of the bearing bracket 170, and the second outer ring 162 of the second bearing 160 is the bearing bracket 170 It can be fixed through an adhesive on the inner surface of the.

11 and 15 together, in a state in which the first bearing 150 and the second bearing 160 are installed on the inner surface of the bearing bracket 170, the separation preventing member 190 is formed of the bearing bracket 170. It may be installed on the bearing bracket 170 to surround the outer circumferential surface (S507).

Specifically, the separation preventing member 190 may contact the first bearing 150, and at least a portion may overlap the outer ring 152 of the first bearing 150 along the axial direction of the rotation shaft 110. . Accordingly, the first bearing 150 may be fixed by the separation preventing member 190 to be seated inside the bearing bracket 170 without deviating in a direction toward the impeller 120.

Meanwhile, referring to FIGS. 11 and 16, the first bearing 150 and the second bearing 160 are installed on the rotating shaft 110 (S501), and the elastic member 180 is inserted into the bearing bracket 270. (S503), the first bearing 150 and the second bearing 160 is installed on the bearing bracket 270 so that the rotation shaft 110 is installed through the bearing bracket 270 until the step (S505) is the same, but the bearing bracket Unlike the bearing bracket 170 shown in FIGS. 12 to 15, the 270 further includes an installation groove 272 that is recessed at a predetermined interval along the radial direction of the rotation shaft 110 from the inner circumferential surface of the bearing bracket 270 can do.

That is, the rotation shaft 110 in which the first bearing 150 and the second bearing 160 are installed is inserted into the bearing bracket 270 having the installation groove 272, and the second outer ring 162 of the second bearing 160 In a state in which a pressing force is applied in a direction toward the first bearing 150 by the elastic member 180, the separation preventing member 290 is installed in the installation groove 272 in a compressed state (refer to 290C in FIG. 6). 1 can support the bearing 150.

As described above, the separation preventing member 290 shown in FIG. 16 is expanded in a compressed state (290C in FIG. 6) compressed according to an external force and in a compressed state (290C) according to an external force. It may be elastically deformable between the normal states (290S in FIG. 6).

That is, the separation preventing member 290 enters the bearing bracket 270 in a compressed state (290C) and is seated in the installation groove 272, and then expands to a normal state (290S) and firmly fits the installation groove 272. Can be fixed. In this way, the separation preventing member 290 installed in the installation groove 272 overlaps with the first outer ring 152 of the first bearing 150 along the axial direction of the rotation shaft 110, so that the first outer ring 152 is a bearing The first outer ring 152 may be fixed to the inside of the bearing bracket 170 so as not to be separated from the bracket 270.

17 is a flowchart schematically illustrating a method of manufacturing the motor assembly illustrated in FIGS. 4 and 8, and FIGS. 18 to 22 are conceptual diagrams sequentially illustrating a method of manufacturing the motor assembly illustrated in FIG. 17.

Referring to FIG. 17, the method of manufacturing the motor assembly 100 shown in FIGS. 4 and 8 is the step of installing the first bearing 150 and the second bearing 160 on the rotating shaft 110 (S1701). Wow, inserting the rotating shaft 110 into the bearing brackets 170 and 270 so that the first bearing 150 and the second bearing 160 are seated on the bearing brackets 170 and 270 (S1703), and the first bearing Inserting the elastic member 180 ′ into the bearing brackets 170 and 270 so that the 150 and the elastic member 180 ′ contact each other (S1705), the elastic member 180 ′ and the separation preventing member 190, It may include a step (S1707) of installing the separation preventing members (190, 290) to the bearing brackets (170, 270) so that the 290 contacts each other.

After the separation preventing members 190 and 290 are installed on the bearing brackets 170 and 270, the elastic member 180 ′ is interposed between the first bearing 150 and the separation preventing members 190 and 290 to form a first bearing ( The first bearing 150 may be pressed in a direction in which the 150 and the second bearing 160 are close to each other.

Referring to FIGS. 17 and 18 together, the first inner ring 151 of the first bearing 150 may be press-fitted to the first support part 112 of the rotation shaft 110, and the second bearing 160 2 The inner ring 161 may be press-fitted to the second support part 113 of the rotation shaft 110 (S1701).

As described above, the first support part 112 and the second support part 113 are located on one side 110A of the rotation shaft 110, but may be spaced apart from each other by a predetermined distance along the axial direction of the rotation shaft 110. Accordingly, the first bearing 150 and the second bearing 160 may also be installed on one side 110A of the rotation shaft 110, and may be disposed to be spaced apart from each other by a predetermined distance along the axial direction of the rotation shaft 110. .

Referring to FIGS. 17 and 19 together, before the elastic member 180 is inserted into the bearing bracket 170, the rotation shaft 110 on which the first bearing 150 and the second bearing 160 are installed is a bearing bracket ( 170) can be inserted and installed (S1703).

At this time, the first bearing 150 and the second bearing 160 may be installed in the inner space of the bearing bracket 170, and the first outer ring 152 of the first bearing 150 is of the bearing bracket 170. It may be attached to the inner surface through an adhesive, and the second outer ring 162 of the second bearing 160 may be fixed to the inner surface of the bearing bracket 170 by press fit.

Referring to FIGS. 17 and 20 together, in a state in which the rotating shaft 110 in which the first bearing 150 and the second bearing 160 are installed is inserted into the inner space of the bearing bracket 170, the elastic member 180' The elastic member 180 ′ may be inserted into the bearing bracket 170 so that the and the first bearing 150 contact each other (S1705).

17 and 21 together, the first bearing 150 and the second bearing 160 are installed inside the bearing bracket 170 and the rotating shaft 110 and the elastic member 180' are installed, The separation preventing member 190 may be installed on the bearing bracket 170 so that the preventing member 190 and the elastic member 180 ′ contact each other (S1707).

Specifically, the separation preventing member 190 may be installed on the bearing bracket 170 so as to surround the outer circumferential surface of the bearing bracket 170. In addition, at least a portion of the separation preventing member 190 may overlap the outer ring 152 of the first bearing 150 along the axial direction of the rotation shaft 110. Accordingly, the first bearing 150 is fixed by the separation preventing member 190 via the elastic member 180 ′ to be seated inside the bearing bracket 170 without deviating in the direction toward the impeller 120. I can.

Meanwhile, referring to FIGS. 17 and 22 together, the first bearing 150 and the second bearing 160 are installed on the rotating shaft 110 (S1701), and the first bearing 150 and the bearing bracket 270 The rotation shaft 110 on which the second bearing 160 is installed is inserted and installed (S1703), and until the step of inserting the elastic member 180' into the bearing bracket 270 to contact each other with the first bearing 150 (S1705) The same, but the bearing bracket 270 shown in Fig. 22, unlike the bearing bracket 170 shown in Figs. 18 to 20, is recessed at a predetermined distance along the radial direction of the rotation shaft 110 from the inner circumferential surface of the bearing bracket 270 It may further include an installation groove 272 formed.

That is, the rotation shaft 110 in which the first bearing 150 and the second bearing 160 are installed is inserted into the bearing bracket 270 having the installation groove 272, and the first outer ring 152 of the first bearing 150 In a state in which a pressing force is applied in the direction toward the second bearing 160 by the elastic member 180 ′, the separation preventing member 290 is installed in the installation groove 272 in a compressed state (see 290C in FIG. 6). The first bearing 150 may be supported.

As described above, the separation preventing member 290 shown in FIG. 22 is expanded in a compressed state (290C in FIG. 6) compressed according to an external force and in a compressed state (290C) according to an external force. It may be elastically deformable between the normal states (290S in FIG. 6).

That is, the separation preventing member 290 enters the bearing bracket 270 in a compressed state (290C) and is seated in the installation groove 272, and then expands to a normal state (290S) and firmly fits the installation groove 272. Can be fixed. In this way, the separation preventing member 290 installed in the installation groove 272 overlaps with the first outer ring 152 of the first bearing 150 through the elastic member 180 ′ along the axial direction of the rotation shaft 110. , The elastic member 180' and the first outer ring 152 may be fixed to the inside of the bearing bracket 170 so that the elastic member 180' and the first outer ring 152 cannot be separated to the outside of the bearing bracket 270. I can.

As described with reference to FIGS. 11 to 22, the motor assembly 100 according to an embodiment of the present invention does not support the other side 110B of the rotation shaft 110 with a separate bearing. Instead, in an embodiment of the present invention, one side 110A of the rotation shaft 110 is eccentrically supported by two bearings 150 and 160, but the bearings 150 and 160 are provided by using the elastic members 180 and 180 ′. ) By applying an appropriate preload to the motor assembly 100, it is possible to reduce noise and vibration by improving the alignment between the two bearings 150 and 160 at the same time.

In addition, two bearings 150 and 160 are accommodated in one bearing bracket 170 and 270, but the two bearings 150 and 160 are arranged to be spaced apart by a predetermined distance along the axial direction of the rotation shaft 110, The structure of the assembly 100 can be simplified, and at the same time, since the rotating shaft 110 can be stably supported, reliability and durability of the bearing structure can be secured.

In addition, the two bearings 150 and 160 eccentrically supporting the rotating shaft 110 have an outer diameter D greater than the inner diameter 140d of the stator 140, so that the size of the bearing can be enlarged to secure sufficient bearing life. have.

This is, according to the eccentric support structure of the rotation shaft 110 of the first bearing 150 and the second bearing 160 and the bearing bracket 170 according to an embodiment of the present invention, the other side (110B) of the rotation shaft 110 Since the rotation shaft 110 can be stably supported without being supported by a bearing, but also the alignment between bearings can be improved by applying an appropriate preload to the bearings 150 and 160, as a possible design consideration. Enlarging the outer diameter D of the bearing 150 and the second bearing 160 means that the life of the bearing structure can be sufficiently secured.

Those of ordinary skill in the technical field related to the present embodiment will appreciate that it may be implemented in variously modified forms without departing from the essential characteristics of the above-described substrate. Therefore, the disclosed embodiments should be considered from an illustrative point of view rather than a limiting point of view. The scope of the embodiments of the present invention is shown in the claims rather than the foregoing description, and all differences within the scope equivalent thereto should be construed as being included in the embodiments of the present invention.

51: inlet body 140: stator
511: inlet 141: stator core
52: motor housing 142: coil
521: outlet 143: insulator
53: supporter 150: first bearing
54: diffuser 151: first inner ring
541: diffuser vane 152: first outer ring
100: motor assembly 153: first rolling member
110: rotation shaft 160: second bearing
111: impeller coupling portion 161: second inner ring
112: first support 162: second outer ring
113: second support 163: second rolling member
114: rotor coupling portion 170, 270: bearing bracket
120: impeller 171, 271: stepped
121: hub 172, 272: mounting groove
122: blade 180, 180': elastic member
130: rotor 190, 290: separation preventing member
131: magnet 290S: normal state
132: first end plate 290C: compressed state
133: second end plate

Claims (20)

Rotating shaft;
An impeller installed on the rotating shaft;
A rotor installed on the rotation shaft to be spaced apart from the impeller by a predetermined distance along the axial direction of the rotation shaft;
A stator surrounding the outer side of the rotor so as to be spaced apart from the rotor along a radial direction of the rotation shaft;
A first bearing installed on the rotation shaft and disposed adjacent to the impeller between the impeller and the rotor to support a first support portion of the rotation shaft;
A second bearing installed on the rotation shaft and disposed adjacent to the rotor between the impeller and the rotor to support a second support portion of the rotation shaft;
A bearing bracket accommodating the first bearing and the second bearing;
It is interposed between the first bearing and the bearing bracket or between the second bearing and the bearing bracket to press one of the first bearing and the second bearing in a direction in which the first bearing and the second bearing become close to each other. An elastic member; And
It is installed on the bearing bracket, at least a portion of which overlaps with each other based on the axial direction of the rotation shaft and one of the first bearing, the second bearing, and the elastic member, and the first bearing, the second bearing, and the elasticity A motor assembly comprising a separation preventing member for fixing the member to the inner space of the bearing bracket. The method of claim 1,
The separation preventing member, characterized in that installed on the bearing bracket to surround the outer peripheral surface of the bearing bracket, motor assembly. The method of claim 1,
The bearing bracket includes an installation groove recessed at a predetermined distance along the radial direction of the rotation shaft from an inner peripheral surface of the bearing bracket,
The separation preventing member is characterized in that it is elastically deformable between a compressed state compressed according to an external force and a normal state expanded in the compressed state as it is removed by an external force,
The separation preventing member, characterized in that installed in the installation groove in the compressed state, motor assembly. The method of claim 3,
The separation preventing member is characterized in that it has a diameter substantially corresponding to or smaller than the diameter of the inner peripheral surface of the bearing bracket in the compressed state, motor assembly. The method of claim 1,
The motor assembly, characterized in that the outer diameter of the first bearing and the outer diameter of the second bearing are larger than the inner diameter of the stator. The method of claim 1,
The first bearing is interposed between a first inner ring press-fitted to an outer circumferential surface of the first support portion of the rotation shaft, a first outer ring contacting the inner surface of the bearing bracket, and the first inner ring and the first outer ring. And a first rolling member supporting a relative rotational motion of the first inner ring with respect to the first outer ring,
The second bearing is interposed between a second inner ring press-fitted to an outer peripheral surface of the second support portion of the rotation shaft, a second outer ring contacting the inner surface of the bearing bracket, and the second inner ring and the second outer ring. And a second rolling member supporting a relative rotational motion of the second inner ring with respect to the second outer ring. The method of claim 6,
One of the first outer ring and the second outer ring is press-fit and fixed to the inner surface of the bearing bracket,
The other one of the first outer ring and the second outer ring is fixed to the inner surface of the bearing bracket through an adhesive. The method of claim 6,
As the elastic member presses one of the first outer ring and the second outer ring to the other side of the first outer ring and the second outer ring,
The first rolling member maintains a state in substantially contact with the first inner ring and the first outer ring,
The second rolling member, characterized in that maintaining a state in substantially contact with the second inner ring and the second outer ring, motor assembly. Installing the first bearing and the second bearing on the rotating shaft;
Inserting an elastic member into the bearing bracket;
Insert the rotation shaft into the bearing bracket so that the rotation shaft in which the first bearing and the second bearing are installed pass through the bearing bracket, and the first bearing and the second bearing so that the second bearing and the elastic member contact each other. Seating on the bearing bracket; And
Including; and installing a separation preventing member in the bearing bracket at least partially overlapping with the first bearing based on the axial direction of the rotation shaft; and
The elastic member is interposed between the second bearing and the bearing bracket to press the second bearing in a direction in which the first bearing and the second bearing are close to each other. The method of claim 9,
The separation preventing member is characterized in that installed on the bearing bracket so as to surround the outer circumferential surface of the bearing bracket. The method of claim 9,
The bearing bracket includes an installation groove recessed at a predetermined distance along the radial direction of the rotation shaft from an inner peripheral surface of the bearing bracket,
The separation preventing member is characterized in that it is elastically deformable between a compressed state compressed according to an external force and a normal state expanded in the compressed state as it is removed by an external force,
The separation preventing member is characterized in that installed in the installation groove in the compressed state, the method of manufacturing a motor assembly. The method of claim 9,
The first inner ring of the first bearing is press-fitted and fixed to the first support portion of the rotation shaft,
A method of manufacturing a motor assembly, characterized in that the second inner ring of the second bearing is press-fitted to the second support portion of the rotation shaft. The method of claim 9,
The first outer ring of the first bearing is press-fitted to the inner surface of the bearing bracket,
A method of manufacturing a motor assembly, characterized in that the second outer ring of the second bearing is fixed to the inner surface of the bearing bracket through an adhesive. The method of claim 13,
The second outer ring of the second bearing is attached to the inner surface of the bearing bracket through the adhesive for a predetermined period of time, as the elastic member presses the second outer ring toward the first outer ring. It is possible to slide a predetermined distance along the axial direction of the rotation shaft along the inner surface of the bracket,
After the predetermined time has elapsed, the second outer ring is fixed to the inner surface of the bearing bracket. Installing the first bearing and the second bearing on the rotating shaft;
Inserting the rotation shaft into the bearing bracket so that the rotation shaft on which the first bearing and the second bearing are installed pass through the bearing bracket, and seating the first bearing and the second bearing on the bearing bracket;
Inserting the elastic member into the bearing bracket so that the first bearing and the elastic member contact each other; And
A method of manufacturing a motor assembly comprising the steps of: installing a separation preventing member in the bearing bracket in which at least a part of the elastic member and the elastic member are in contact with each other based on the axial direction of the rotation shaft. The method of claim 15
The separation preventing member is characterized in that installed on the bearing bracket so as to surround the outer circumferential surface of the bearing bracket. The method of claim 15,
The bearing bracket includes an installation groove recessed at a predetermined distance along the radial direction of the rotation shaft from an inner peripheral surface of the bearing bracket,
The separation preventing member is characterized in that it is elastically deformable between a compressed state compressed according to an external force and a normal state expanded in the compressed state as it is removed by an external force,
The separation preventing member is characterized in that installed in the installation groove in the compressed state, the method of manufacturing a motor assembly. The method of claim 19,
The elastic member is interposed between the first bearing and the separation preventing member to press the first bearing in a direction in which the first bearing and the second bearing are close to each other. The method of claim 15,
The first outer ring of the first bearing is fixed to the inner surface of the bearing bracket through an adhesive,
A method of manufacturing a motor assembly, characterized in that the second outer ring of the second bearing is press-fitted to the inner surface of the bearing bracket. The method of claim 19,
The first outer ring of the first bearing is attached to the inner surface of the bearing bracket through the adhesive for a predetermined period of time, as the elastic member presses the first outer ring toward the second outer ring. It is possible to slide a predetermined distance along the axial direction of the rotation shaft along the inner surface of the bracket,
After the lapse of the predetermined time, the first outer ring is fixed to the inner surface of the bearing bracket.

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