KR20240050605A - Brushless dc motor with novel ground structure - Google Patents

Abstract

The brushless DC motor (1) according to the present invention includes a housing (30) that includes a stator (10) therein and has a hollow portion (31) in the center where a rotor (20) to which a shaft (21) is coupled is located; an upper bearing (22) coupled to the output side of the shaft (21) to rotatably support the shaft; a lower bearing 23 coupled to the lower end of the shaft 21 and rotatably supporting the shaft; An upper cover 40 that accommodates the upper bearing 22 and covers the hollow portion 31; a lower cover 50 that accommodates the lower bearing 23 and is coupled to the lower center of the housing 30; and a conductive material applied to the housing 30 to electrically connect the upper cover 40 and the lower cover 50 to electrically equal potential. It is characterized in that it includes an application part (60).

Description

BLDC motor with improved ground structure {BRUSHLESS DC MOTOR WITH NOVEL GROUND STRUCTURE}

The present invention relates to motors. More specifically, the present invention relates to a motor having a grounding structure that improves the performance, durability, vibration, and noise of the motor by improving the grounding structure to more effectively prevent bearing corrosion.

Typically, a motor includes a stator and a rotor. The rotor rotates under the influence of the magnetic field formed by the stator. A shaft that is coupled to the rotor and rotates with the rotor has bearings installed at the top and bottom of the rotor to support the rotation of the shaft.

These motors are generally controlled by a drive circuit, and when the drive circuit operates, electrical corrosion of the bearing occurs due to a potential difference generated between the upper and lower bearings or due to axial current generated for other reasons. Due to this electrical corrosion, noise and vibration are generated when the motor operates, which adversely affects the performance of the motor and the durability of the motor.

In order to prevent electrical corrosion of such bearings, in Korean Patent Publication No. 10-2008-0109168, the output side bracket surrounding the upper bearing and the semi-output side bracket surrounding the lower bearing are connected with conductive tape to form an equal potential on both sides. A technology for preventing electrical corrosion of bearings is disclosed. However, the structure of the part that secures the ends of the conductive tape is weak, so problems may arise in maintaining equal potential. Additionally, if the adhesive strength of the conductive tape is not guaranteed, grounding performance is bound to deteriorate.

Meanwhile, Republic of Korea Patent No. 10-1562736 proposes a structure in which a grounding metal member is installed on the outside of the motor housing and the upper and lower ends of the grounding metal member are directly connected to the upper bearing cover and the lower bearing cover. This prior art effectively achieves grounding between the upper and lower bearing covers, but because the bearings are inserted into the outside of the upper and lower bearing covers, the two bearings are easily exposed to the outside. In particular, since the end of the grounding metal member is in slight contact with the lower bearing cover, there is a risk of the grounding member coming off, which may lead to a problem of not effectively blocking the occurrence of bearing corrosion.

In Korean Patent Nos. 10-1604900 and 10-2041045, upper and lower bearings are installed in a housing, parts of the upper and lower bearings are exposed, and a ground member connects each exposed bearing to achieve equal potential. According to this structure, grounding members must be installed on exposed portions of the upper and lower bearings, which may be disadvantageous in terms of assembly and productivity.

Accordingly, in order to solve the above-mentioned problems, the present inventors would like to propose a motor with an improved grounding structure that was not proposed in the prior art.

The object of the present invention is to provide a brushless DC motor with an improved grounding structure.

Another object of the present invention is to provide a brushless DC motor that can more effectively prevent electrostatic corrosion of bearings by maintaining the upper and lower covers at equal potential by applying a conductive material.

Another object of the present invention is to provide a brushless DC motor with improved assemblyability and productivity.

The above objectives and other inherent objectives of the present invention can all be easily achieved by the present invention described below.

The brushless DC motor (1) according to the present invention includes a housing (30) that includes a stator (10) therein and has a hollow portion (31) in the center where a rotor (20) to which a shaft (21) is coupled is located;

an upper bearing (22) coupled to the output side of the shaft (21) to rotatably support the shaft;

a lower bearing 23 coupled to the lower end of the shaft 21 and rotatably supporting the shaft;

an upper cover 40 that accommodates the upper bearing 22 and covers the hollow portion 31;

a lower cover 50 that accommodates the lower bearing 23 and is coupled to the lower center of the housing 30; and

Applying a conductive material to the housing 30 to electrically connect the upper cover 40 and the lower cover 50 to electrically equal potential. It is characterized in that it includes a unit (60).

In the present invention, an upper flange seating portion 34 is formed in an annular shape along the upper circumference of the hollow portion 31 for seating the upper cover flange 43 of the upper cover 40, and the upper flange seating portion 34 is formed in an annular shape. The part 34 preferably forms the upper part of the hollow part 31 and the upper step part 35.

In the present invention, the upper end of the conductive material application portion 60 may have a first upper end portion 61 applied up to the upper step portion 35.

In the present invention, the upper end of the conductive material application portion 60 has a second upper end portion 62 applied and extending from the first upper end portion 61 to the upper flange seating portion 34. good night.

In the present invention, the lower cover 50 has a lower flange seating portion 36 formed in the central hole 33 of the bottom 32 of the housing 30 to be coupled to the lower flange seating portion 36. ) and the bottom of the bottom 32 of the housing 30 form a lower step 37, and the lower end of the conductive material application portion 60 forms a lower step ( It is desirable to have a first lower end portion 63 onto which a conductive material is applied.

In the present invention, a second lower end portion 64 may be provided that extends from the first lower end portion 63 to the lower flange seating portion 36 to which a conductive material is applied.

The brushless DC motor (1) according to the present invention includes a housing (30) that includes a stator (10) therein and has a hollow portion (31) in the center where a rotor (20) to which a shaft (21) is coupled is located;

an upper bearing (22) coupled to the output side of the shaft (21) to rotatably support the shaft;

a lower bearing 23 coupled to the lower end of the shaft 21 and rotatably supporting the shaft;

an upper cover 40 that accommodates the upper bearing 22 and covers the hollow portion 31;

a lower cover 50 that accommodates the lower bearing 23 and is coupled to the lower center of the housing 30; and

Includes a conductive material application portion 60 applied to the upper cover 40, the lower cover 50, and the housing 30 to electrically equalize the upper cover 40 and the lower cover 50. It is characterized by:

The present invention can effectively maintain the equal potential between the upper and lower bearings through a new grounding structure that brings the upper and lower covers into contact at the same time, thereby preventing corrosion of the bearings more effectively and improving assembly and productivity. has

1 is a perspective view of a brushless DC motor according to the present invention.
Figure 2 is a perspective view from above of the lower part of the brushless DC motor according to the present invention.
Figure 3 is a perspective view of the brushless DC motor according to the present invention disassembled and viewed from the top.
Figure 4 is a perspective view of the brushless DC motor according to the present invention disassembled and viewed from the bottom.
Figure 5 is a perspective view of the housing viewed from above to show the grounding structure of the upper cover of the brushless DC motor according to the present invention.
Figure 6 is a perspective view showing the lower part of the housing upward to show the grounding structure of the lower cover of the brushless DC motor according to the present invention.
Hereinafter, the present invention will be described in detail with reference to the attached drawings.

Figure 1 is a perspective view of a brushless DC motor (1) according to the present invention, Figure 2 is a perspective view of the lower part of the brushless DC motor (1) according to the present invention viewed from above, and Figure 3 is a perspective view of the brushless DC motor (1) according to the present invention. It is a perspective view of the DC motor 1 disassembled and viewed from the top, and Figure 4 is a perspective view of the brushless DC motor 1 according to the present invention disassembled and viewed from the bottom.

As shown in Figures 1 to 4, the brushless DC motor 1 according to the present invention includes a stator 10, a rotor 20, a housing 30, an upper cover 40, a lower cover 50, and It may include a conductive material application portion 60.

The stator 10 includes a plurality of teeth 11 protruding in the direction of the shaft 21 and a printed circuit board 12 electrically connected to the stator. The printed circuit board 12 is electrically connected to the connector 13, and the lead wire 14 is electrically connected to the connector 13 to exchange external power or signals.

The rotor 20 is located in the inner space of the stator 10 and rotates by changes in the magnetic field generated in the stator 10. For this purpose, the rotor 20 includes a magnet located inside facing the stator 10. A shaft 21 penetrates and is coupled to the center of the rotor 20. Accordingly, the rotor 20 and shaft 21 become one unit and rotate together. A load such as a fan is coupled to the top of the shaft 21. That is, the upper end of the shaft 21 becomes the output side. An upper bearing 22 is coupled to the lower part of the top of the shaft 21 to support the rotation of the shaft 21. A lower bearing 23 is coupled to the lower part of the shaft 21 to support the rotation of the shaft 21.

The housing 30 consists of a hollow part 31 with an empty space in the middle, and a bottom part 32 that covers the lower part of the hollow part 31. A rotor 20 that is coupled to the shaft 21 and rotates together is located in the hollow portion 31. A central hole 33 for attaching the lower cover 50 is formed in the center of the bottom 32. On the inner peripheral surface of the central hole 33, a plurality of press-fit protrusions 33A are formed to protrude in the direction of the shaft 21 at regular intervals from each other.

Inside the housing 30, the stator 10 is installed to face the side of the rotor 20. 3 and 4, the stator 10 and the housing 30 are shown as separate parts, but the stator 10, the printed circuit board 12, and the connector 13 are separated from the housing 30 in the insert mold. It is preferable that it is manufactured integrally with the injection molding.

The upper cover 40 is made of a conductive metal material and is coupled to cover the upper part of the hollow portion 31 of the housing 30. The upper cover 40 includes a disk-shaped upper cover body 41, a lower protrusion 42 protruding from the lower part of the upper cover body 41, and an upper cover forming the outer circumference of the upper cover body 41. It consists of a flange 43, an upper bearing insertion portion 44 having a shape that protrudes upward in the central part of the upper cover body 41, and an upper shaft through hole 45 through which the shaft 21 passes.

The upper bearing 22 is coupled to the protruding inner portion of the upper bearing insertion portion 44. The upper bearing 22 is shown in FIG. 3 as being coupled to the lower side of the upper bearing insertion portion 44, but the shape is not necessarily limited to this, and the upper bearing 22 is coupled to the upper side of the upper cover 40. The shape of the upper bearing insertion portion 44 of the upper cover 40 may be changed by opening the central portion upward.

The lower cover 50 includes a lower cover body 51 made of a conductive material and having a cup shape with an open top, a lower cover flange 52 extending to the upper peripheral portion of the lower cover body 51, and a lower bearing. In order to be inserted, it includes a lower bearing insertion portion 53, which is an inner space of the lower cover body 51, and a lower shaft penetration hole 54 formed at the center of the bottom of the lower cover body 51 for the shaft 21 to pass through. do. A plurality of press-fit grooves 52A are formed at regular intervals in the lower cover flange 52. The press-fit groove 52A is a groove into which the press-fit protrusion 33A formed inside the central hole 33 of the bottom 32 of the housing 30 is press-fitted.

The conductive material application part 60 is configured to electrically connect the upper cover 40 and the lower cover 50 to achieve equal potential. The housing is used to electrically connect the upper cover 40 and the lower cover 50 to each other. It is a conductive material applied to (30). These conductive materials may be materials such as conductive ink or conductive paint that can be applied to the surface of the housing 30 to electrically connect the upper cover 40 and the lower cover 50. In the present invention, the conductive material application portion 60 can be applied in two embodiments.

In one embodiment, in FIGS. 1 and 2, a conductive material application portion 60 made by applying a conductive material is formed uniformly on the upper, side, and lower surfaces of the housing, and the upper cover flange of the upper cover 40 A conductive material application portion 60 is also formed on a portion of 43 and a portion of the side surface of the lower cover 40. When applying the conductive material application portion 60 with this structure, the upper cover 40 and the lower cover 50 are assembled to the housing 30, and then a process of applying the conductive material is performed. Accordingly, assembly is improved and electrical connection between the upper and lower covers 40 and 50 can be made more easily.

In another embodiment, in FIGS. 3 and 4, before assembling the upper cover 40 and the lower cover 50 to the housing 30, a conductive material application portion 60 is formed on the housing 30, thereby enabling conduction. The upper and lower end structures of the material application portion 60 have unique structures. In this embodiment, the upper cover 40 and the lower cover 50 are assembled to the housing 30 to form an electrical connection with the conductive material application portion 60. For a more detailed structure, refer to FIGS. 5 and 6 below. Let me explain.

Figure 5 is a perspective view of the housing 30 viewed from above to show the grounding structure of the upper cover of the brushless DC motor 1 according to the present invention. As shown in Figure 5, the housing 30 of the present invention has an open top shape and has a hollow portion 31, which is an internal space. An upper flange seating portion 34 is formed in an annular shape along the upper circumference of the hollow portion 31. The upper flange seating portion 34 is formed to be lower in height than the upper part of the housing 30, and the portion where there is a height difference forms the upper step portion 35. The upper cover flange 43 of the upper cover 40 is seated on the upper flange seating portion 34, and the outermost circumference of the upper cover flange 43 is press-fitted into the upper step portion 35.

The upper end of the conductive material application portion 60 may be comprised of a first upper end portion 61 and a second upper end portion 62. The first upper end portion 61 is a portion where a conductive material is applied to the upper step portion 35, and the second upper end portion 62 extends from the first upper end portion 61 to form an upper flange seating portion 34. ) is the part where the conductive material is applied.

In the present invention, the upper end of the conductive material application portion 60 may be used as the first upper end portion 61, and in order to increase the reliability of the electrical connection between the conductive material application portion 60 and the upper cover 40, the conductive material application portion 60 may be used as the first upper end portion 61. The upper end of the material application portion 60 may be a second upper end portion 62 extending further from the first upper end portion 61.

Figure 6 is a perspective view of the lower part of the housing 30 viewed from above to show the grounding structure of the lower cover 50 of the brushless DC motor 1 according to the present invention.

The housing 30 of the present invention includes a bottom 32 having a central hole 33. A plurality of press-fit protrusions 33A are formed around the inner circumference of the central hole 33 to be press-fitted into the press-fit groove 52A of the lower cover 50. The lower cover flange 52 of the lower cover 50 is seated on the lower flange seating portion 36, and the lower flange seating portion 36 is formed to be higher than the lower portion of the housing 30.

The bottom surface of the lower flange seating portion 36 and the bottom portion 32 have a height difference, and the portion with this height difference forms the lower step portion 37. The lower cover flange 52 of the lower cover 50 is seated on the lower flange seating portion 36. A plurality of press-fitting protrusions 33A are preferably formed on the lower step portion 37.

The lower end of the conductive material application portion 60 may be comprised of a first lower end portion 63 and a second lower end portion 64. The first lower end portion 63 is a portion where a conductive material is applied to the lower step portion 37, and the second lower end portion 64 extends from the first lower end portion 63 to form a lower flange seating portion 36. ) is the part where the conductive material is applied.

In the present invention, the lower end of the conductive material application portion 60 may be used as the first lower end portion 63, and in order to increase the reliability of the electrical connection between the conductive material application portion 60 and the lower cover 50, the conductive material application portion 60 may be used as the first lower end portion 63. The lower end of the material application portion 60 may be a second lower end portion 64 extending further from the first lower end portion 63. In addition, the second lower end portion 64 is preferably applied including the press-fitting protrusion 33A formed on the lower step portion 37 in terms of improving electrical connection reliability.

It should be noted that the description of the present invention described above is merely an example for understanding the present invention and is not intended to define the scope of the present invention. The scope of the present invention is defined by the claims attached below, and any simple modification or change of the present invention within this scope should be understood as falling within the scope of protection of the present invention.

1: motor 10: stator
11: Teeth 12: Printed circuit board
13: Connector 14: Lead wire
20: rotor 21: shaft
22: upper bearing 23: lower bearing
30: Housing 31: Hollow part
32: bottom 33: central hole
33A: Press-fit protrusion 34: Upper flange seating portion
35: upper step portion 36: lower flange seating portion
37: lower step 40: upper cover
41: upper cover body 42: lower protrusion
43: upper cover flange 44: upper bearing insertion part
45: Upper shaft through hole 50: Lower cover
51: lower cover body 52: lower cover flange
52A: Press-fit groove 53: Lower bearing insertion part
54: Lower shaft penetration hole 60: Applicator
61: first upper distal region 62: second upper distal region
63: first lower distal region 64: second lower distal region

Claims (7)

A housing 30 including a stator 10 therein and having a hollow portion 31 in the central portion where a rotor 20 to which a shaft 21 is coupled is located;
an upper bearing (22) coupled to the output side of the shaft (21) to rotatably support the shaft;
a lower bearing 23 coupled to the lower end of the shaft 21 and rotatably supporting the shaft;
an upper cover 40 that accommodates the upper bearing 22 and covers the hollow portion 31;
a lower cover 50 that accommodates the lower bearing 23 and is coupled to the lower center of the housing 30; and
Applying a conductive material to the housing 30 to electrically connect the upper cover 40 and the lower cover 50 to electrically connect the upper cover 40 and the lower cover 50. A brushless DC motor comprising a unit (60). The method of claim 1, wherein an upper flange seating portion 34 is formed in an annular shape along the upper circumference of the hollow portion 31 for seating the upper cover flange 43 of the upper cover 40, and the upper flange seating portion 34 is formed in an annular shape. A brushless DC motor, wherein the flange seating portion (34) forms the upper part of the hollow portion (31) and the upper stepped portion (35). The brushless DC motor according to claim 2, wherein the upper end of the conductive material application portion (60) has a first upper end portion (61) applied up to the upper step portion (35). The method of claim 3, wherein the upper end of the conductive material application portion (60) extends from the first upper end portion (61) to the upper flange seating portion (34) to form a second upper end portion (62) applied thereto. A brushless DC motor characterized by having. The method of claim 1, wherein the lower cover 50 has a lower flange seating portion 36 formed in the central hole 33 of the bottom 32 of the housing 30 to be coupled to the lower flange seating portion. The portion where there is a height difference between (36) and the bottom of the bottom 32 of the housing 30 forms a lower step 37, and the lower end of the conductive material application portion 60 forms a lower step. A brushless DC motor, characterized in that the portion (37) has a first lower end portion (63) coated with a conductive material. The brushless brush according to claim 5, characterized in that it has a second lower end portion (64) extending from the first lower end portion (63) to the lower flange seating portion (36) to which a conductive material is applied. DC motor. A housing 30 including a stator 10 therein and having a hollow portion 31 in the central portion where a rotor 20 to which a shaft 21 is coupled is located;
an upper bearing (22) coupled to the output side of the shaft (21) to rotatably support the shaft;
a lower bearing 23 coupled to the lower end of the shaft 21 and rotatably supporting the shaft;
an upper cover 40 that accommodates the upper bearing 22 and covers the hollow portion 31;
a lower cover 50 that accommodates the lower bearing 23 and is coupled to the lower center of the housing 30; and
It includes a conductive material application portion 60 applied to the upper cover 40, the lower cover 50, and the housing 30 to electrically equalize the upper cover 40 and the lower cover 50. A brushless DC motor characterized in that.

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