KR102717137B1 - Stator assembly for brushless direct current blower motor - Google Patents

Abstract

A stator assembly of a blower motor according to the present invention comprises: a stator core (10) including a core base (101) having a cylindrical shape; and a plurality of teeth (102) formed radially at regular intervals on an outer surface of the core base (101); an upper insulator (11) coupled to an upper portion of the stator core (10); and a lower insulator (12) coupled to a lower portion of the stator core (10); wherein the stator core (10) is characterized by including a central cylindrical body (103) positioned on the inner side of the core base (101) and having a central coupling hole (103A) formed on the inner side thereof, and a plurality of through holes (105) formed in a space between the core base (101) and the central cylindrical body (103).

Description

{STATOR ASSEMBLY FOR BRUSHLESS DIRECT CURRENT BLOWER MOTOR}

The present invention relates to a blower motor used in an air conditioning device of a vehicle, etc. More specifically, the present invention relates to a stator assembly of a blower motor capable of reducing the size and weight of the blower motor and preventing overheating of the motor by applying a stator assembly having a novel structure.

In general, automobiles need to have the ability to bring in high or low temperature air into the vehicle to control the interior temperature or humidity, and the circulation of air for controlling the temperature and humidity is achieved by the rotation of a blower fan. The blower fan is driven by a blower motor.

A blower motor of this type includes a rotor, a stator, and a housing that accommodates the rotor and the stator. When current is applied to a coil wound on a stator core, the rotor rotates due to electromagnetic interaction with the stator, thereby rotating a fan assembly installed on the rotational axis of the rotor, thereby performing an air conditioning function.

Korean Patent No. 10-1755881 discloses a structure in which a step is formed on the contact surface of a heat sink so that air flowing into a blower motor can be concentrated toward the element that is the main source of heat generation in order to effectively dissipate heat from the element mounted on the printed circuit board. This prior art mentions a structure for cooling the heat generated from the element, but does not mention how to handle the heat generated from the stator.

Accordingly, the inventors of the present invention propose a stator assembly of a blower motor having a novel structure capable of effectively cooling heat generated from a stator assembly and a printed circuit board and minimizing the size and weight of the blower motor.

The purpose of the present invention is to provide a new structural stator assembly capable of reducing the size and weight of a motor.

Another object of the present invention is to provide a novel stator assembly having a structure capable of effectively cooling heat generated from a stator assembly and a printed circuit board.

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

The stator assembly of the blower motor according to the present invention

A stator core (10) including a core base (101) having a cylindrical shape and a plurality of teeth (102) formed radially at regular intervals on the outer surface of the core base (101); and

An upper insulator (11) coupled to the upper portion of the stator core (10);

Including,

The above stator core (10) is characterized by including a central cylindrical body (103) positioned on the inside of the core base (101) and having a central joining hole (103A) formed on the inside, and a plurality of through holes (105) formed in the space between the core base (101) and the central cylindrical body (103).

In the present invention, it is preferable to further include a plurality of ribs (104) connecting the outer peripheral portion of the core base (101) and the inner peripheral portion of the central cylinder.

In the present invention, the upper insulator (11) may include an upper base (111) positioned above the core base (101), an upper tooth portion (112) for covering and insulating the upper side of the tooth (102), a first annular protrusion (113) formed by protruding upward from the upper base (111), and a second annular protrusion (114) having an upper central space (114A) and positioned above the central cylinder (103).

In the present invention, a plurality of flow paths (116) formed between the first annular protrusion (113) and the second annular protrusion (114) may be further included.

In the present invention, a plurality of connecting ribs (115) connecting the first annular protrusion (113) and the second annular protrusion (114) may be further included.

In the present invention, it is preferable that an upper bearing (B1) is inserted into the upper central space (114A).

In the present invention, the outer surface of the first annular protrusion (113) may have a plurality of coil guides (117) formed to protrude radially at regular intervals.

The stator assembly of the blower motor according to the present invention

A stator core (10) including a core base (101) having a cylindrical shape and a plurality of teeth (102) formed radially at regular intervals on the outer surface of the core base (101); and

An upper insulator (11) coupled to the upper portion of the stator core (10);

Including,

The upper insulator (11) includes an upper base (111) positioned on the upper side of the core base (101), an upper tooth portion (112) for covering and insulating the upper side of the tooth (102), a first annular protrusion (113) formed by protruding upward from the upper base (111), and a second annular protrusion (114) having an upper central space (114A) and positioned on the upper side of the central cylinder (103).

It is characterized by further including a plurality of paths (116) formed between the first annular protrusion (113) and the second annular protrusion (114).

The present invention has the effects of providing a stator assembly of a blower motor having a new structure, which can reduce the size and weight of the motor, effectively cool the heat generated from the stator assembly and the printed circuit board, and so on.

Figure 1 is a perspective view showing a blower motor according to the present invention.
Figure 2 is a cutaway perspective view taken along line A-A' of Figure 1.
Figure 3 is a perspective view showing an exploded view of a blower motor according to the present invention.
Figure 4 is a perspective view of the blower motor according to the present invention, viewed from below, disassembled.
Figure 5 is a perspective view showing a stator core of a blower motor according to the present invention.
Figure 6 is a perspective view showing a stator assembly of a blower motor according to the present invention.
Figure 7 is a perspective view of the stator assembly of the blower motor according to the present invention as viewed from below.
The present invention will be described in detail below with reference to the attached drawings.

FIG. 1 is a perspective view showing a blower motor according to the present invention, FIG. 2 is a cut-away perspective view taken along line A-A' of FIG. 1, FIG. 3 is an exploded perspective view showing a blower motor according to the present invention, and FIG. 4 is a exploded perspective view looking from below of a blower motor according to the present invention.

As shown in FIGS. 1 to 4, a blower motor according to the present invention includes a motor assembly (100), a flange (200), and a damper plate (300).

The motor assembly (100) includes a stator assembly (1), a rotor assembly (2), a stator block (3), a printed circuit board (4), and a motor cover (5). The motor assembly (100) is mounted on a flange (200), and a damper plate (300) is coupled to the flange (200) to prevent the motor assembly (100) from being detached.

The stator assembly (1) of the present invention includes a stator core (10), an upper insulator (11), and a lower insulator (12). The stator core (10) includes a core base (101) having a cylindrical shape, and a plurality of teeth (102) formed radially at regular intervals on an outer surface of the core base (101). The upper insulator (11) is coupled to the upper portion of the stator core (10), and the lower insulator (12) is coupled to the lower portion of the stator core (10). A coil (C) is wound on the teeth (102) according to a predetermined pattern. The ends of the wound coils (C) are electrically connected to a first terminal terminal (T1) and a second terminal terminal (T2) that are installed to protrude downward from the lower insulator (12).

The rotor assembly (2) includes a shaft (21), a cup-shaped rotor housing (22) to which the shaft (21) is coupled and which rotates together with the shaft (21), and a plurality of magnets (23) attached at regular intervals along the inner wall of the rotor housing (22). The rotor assembly (2) is installed to surround the stator assembly (1) and rotates by a changing magnetic field generated in the stator assembly (1). The shaft (21) is rotatably supported by an upper bearing (B1) and a lower bearing (B2). The upper bearing (B1) is installed in the central portion of the upper insulator (11). The lower bearing (B2) is installed in the central portion of the stator block (3).

A stator assembly (1) is coupled to the upper part of the stator block (3), and a printed circuit board (4) is positioned at the lower part of the stator block (3). The stator block (3) includes a circular plate (30), a hollow protrusion (31) formed to protrude upwardly in the central part of the plate (30), a protruding connecting part (32) formed to protrude radially at a predetermined interval around the periphery of the plate (30), a through hole (33) formed to penetrate vertically around the hollow protrusion (31) of the plate (30) so that the first and second terminals (T1) (T2) may pass through, an insulating member (34) for blocking the through hole (33), and an element groove (35) for accommodating a portion where some elements mounted on the printed circuit board (4) protrude. The plate (30) is preferably made of aluminum having high electrical and thermal conductivity.

A stator assembly (1) is coupled to a hollow projection (31) of a stator block (3). A lower bearing (B2) that supports a shaft (21) so as to be rotatably supported is coupled to an inner space (31A) formed on the inner side of the hollow projection (31).

The printed circuit board (4) includes a substrate (40) on which various components are mounted, and a connector (41) installed on one side of the substrate (40) to be connected to an external power source. The first and second terminals (T1) (T2) are physically and electrically connected to the substrate (40). The circuit formed on the substrate (40) is electrically connected to the plate (30) of the stator block (3) and allows the circuit to be grounded.

The motor cover (5) includes a cup-shaped cover body (50), a connector coupling portion (51) formed by opening a side portion of the cover body (50), a packing portion (52) formed along the upper circumference of the cover body (50), a plurality of damper portions (53) formed by protruding upward at a predetermined interval along the upper circumference of the cover body (50), a central protrusion (54) formed by protruding upward from the lower central portion of the cover body (50), and a central groove portion (54A) formed in the lower central portion of the cover body (50) and forming an inner space of the central protrusion (54).

A connector (41) is connected to a connector joint (51). A packing portion (52) is formed of a material such as rubber on the periphery of the cover body (50) and also on the periphery of the connector joint (51). Accordingly, when the motor cover (5) is connected to the stator block (3), the internal space of the motor cover (5) is sealed from the outside, thereby preventing moisture from flowing in from the lower side of the motor cover (5).

The damper part (53) is formed by protruding upwardly around the periphery of the cover body (50) with a material such as rubber. The protruding connecting part (32) of the stator block (3) is connected to the damper part (53). Therefore, the position and number of the protruding connecting parts (32) are formed to be the same as the position and number of the damper part (53). In addition, the damper part (53) is located at the damper mounting part (203) of the flange (200) and has a decoupling function that prevents vibration generated in the motor assembly (100) from being transmitted to the flange (200).

The central protrusion (54) is positioned in the inner space (31A) of the stator block (3), and when the shaft (21) of the rotor assembly (2) is pressed into the lower bearing (B2), the upper surface of the central protrusion (54) supports the lower end of the shaft (21). At this time, a jig (not shown) is positioned in the central groove (54A), which is the inner space of the central protrusion (54), so that the upper surface of the central protrusion (54) supports the lower end of the shaft (21).

The flange (200) includes a flange body (201) having a hole formed in the center into which a motor assembly (100) is inserted; an annular upper protrusion (202) formed by protruding upward along the periphery of the hole into which the motor assembly (100) is inserted; a damper mounting portion (203) formed in a groove shape at a position corresponding to a damper portion (53) of the motor assembly (100); and a joining protrusion (204) formed in a protrusion shape at a lower portion of the flange body (201) at a position corresponding to a fastening portion (302) of a damper plate (300).

A part of the rotor assembly (2) is positioned and rotates on the inner side of the upper protrusion (202). The damper mounting portion (203) has a groove shape and the damper portion (53) of the motor cover (5) is mounted thereon. Since the damper portion (53) is a buffer member made of a material such as rubber, it absorbs vibrations generated in the motor assembly (100). The damper portion (53) is mounted on the damper mounting portion (203) of the flange (200), but vibrations generated in the motor assembly (100) can be reduced by this damper portion (53).

The damper plate (300) has a ring-shaped annular body (301), a plurality of fastening portions (302) formed by protruding upward at a predetermined interval from the circumference of the annular body (301), and a plurality of protruding guides (303) formed by protruding toward the shaft (21) at a predetermined interval from the circumference of the annular body (301). A fastening hole (302A) is formed in the fastening portion (302), and the fastening hole (302A) is coupled with a coupling protrusion (204). Of course, the shape of the fastening hole (302A) may be changed to a protrusion shape, and the shape of the coupling protrusion (204) may be changed to a hole or groove shape. The protruding guide (303) supports the motor cover (5) to prevent the motor assembly (100) from being detached downward.

Figure 5 is a perspective view showing a stator core (10) of a blower motor according to the present invention.

As illustrated in FIG. 5, a stator core (10) of a blower motor according to the present invention includes a core base (101) having a cylindrical shape with an inner hollow surface, a plurality of teeth (102) formed radially from an outer circumference of the core base (101), a central cylindrical body (103) positioned on the inner side of the core base (101) and having a central joining hole (103A) formed on the inner side, a plurality of ribs (104) connecting an outer peripheral portion of the core base (101) and an inner peripheral portion of the central cylindrical body, and a plurality of through holes (105) formed in a space between the core base (101) and the central cylindrical body (103). The stator core (10) is manufactured by continuously forming and laminating a thin electrical steel plate by press stamping.

A coil (C) is wound on each tooth (102) while being insulated by upper and lower insulators (11) and (12). A protruding joint (32) of a stator block (3) is press-fitted into a central joint hole (103A) on the inside of the central cylinder (103). A plurality of through holes (105) serve to release heat generated in the stator core (10), etc., by providing air passages.

FIG. 6 is a perspective view showing a stator assembly (1) of a blower motor according to the present invention, and FIG. 7 is a perspective view of the stator assembly (1) of a blower motor according to the present invention as viewed from below.

Referring to FIGS. 6 and 7 together, a stator assembly (1) of a blower motor according to the present invention includes a stator core (10), an upper insulator (11) coupled to an upper portion of the stator core (10), and a lower insulator (12) coupled to a lower portion of the stator core (10).

The upper insulator (11) includes an upper base (111) positioned on the upper side of the core base (101) of the stator core (10), an upper tooth portion (112) for covering and insulating the upper side of the teeth (102), a first annular protrusion (113) formed by protruding upward from the upper base (111), a second annular protrusion (114) having an upper central space (114A) and positioned on the upper side of the central cylinder (103), a plurality of connecting ribs (115) connecting the first annular protrusion (113) and the second annular protrusion (114), and a plurality of flow paths (116) formed between the first annular protrusion (113) and the second annular protrusion (114).

An upper bearing (B1) is coupled to the upper central space (114A). In the present invention, the structure of coupling the upper bearing (B1) to the upper insulator (11) of the stator assembly (1) eliminates the need for application of other parts to couple the upper bearing (B1), thereby enabling miniaturization and weight reduction of the motor.

The euro (116) is formed to be in vertical communication with the through hole (105) formed in the stator core (10). Therefore, it helps to cool the heat generated from the stator core (10), etc.

The outer surface of the first annular protrusion (113) has a coil guide (117) formed by protruding radially at a certain interval. The coil guide (117) serves to prevent the wound coil (C) from moving away from its original position when the coil is wound on the upper tooth portion (112).

The lower insulator (12) includes a lower base (121) positioned at the lower portion of the core base (101) of the stator core (10), a lower tooth portion (122) for covering and insulating the lower portion of the teeth (102), a lower annular protrusion (123) formed by protruding downward from the lower base (121), and an inner support portion (124) formed by protruding in the shaft direction from the lower base (121) and having a joining space (124A) at the center.

The lower annular protrusion (123) has at least one first terminal groove (123A) and at least one second terminal groove (123B). A first terminal terminal (T1) is coupled to the first terminal groove (123A), and a second terminal terminal (T2) is coupled to the second terminal groove (123B). An end of a coil wound on the stator assembly (1) is electrically connected to the first terminal terminal (T1) and the second terminal terminal (T2). One end of a coil forming each phase of the motor is electrically connected to the first terminal terminal (T1), and a coil connecting a neutral point of each phase is electrically connected to the second terminal terminal (T2). The number of the first terminal terminal (T1) and the second terminal terminal (T2) can be applied in various ways depending on the specifications of the motor, the number of phases, etc. The first terminal groove (123A) and the second terminal groove (123B) may have a shape of a hole rather than a groove despite their names.

The protruding joint part (32) of the stator block (3) is coupled to the coupling space (124A), which is the inner space of the inner support part (124). The coupling guide (125) (illustrated in FIG. 3) formed by protruding at a certain interval toward the upper side of the inner support part (124) can be coupled to the inner side of the flow path (116) of the stator core (10).

It should be noted that the description of the invention described above is merely an example for the purpose of 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 appended claims, and it should be understood that all simple modifications or changes of the present invention within this scope fall within the protection scope of the present invention.

1: Stator assembly 2: Rotor assembly
3: Stator block 4: Printed circuit board
5: Motor cover 10: Stator core
11: Upper insulator 12: Lower insulator
21: Shaft 22: Rotor Housing
23 : Magnet 30 : Plate
31: Hollow protrusion 31A: Inner space
32: Protruding joint 33: Through hole
34: Insulating member 35: Element home
40: Board 41: Connector
50: Cover body 51: Connector joint
52: Packing section 53: Damper section
54: Central protrusion 54A: Central groove
100 : Motor Assembly 101 : Core Base
102: Teeth 103: Central cylinder
103A: Center joint 104: Rib
105 ; Through hole 111 : Upper base
112: Upper teeth part 113: First annular projection
114: Second annular projection 114A: Upper central space
115 : Connecting rib 116 : Euro
117 : Coil guide 121 : Lower base
122: Lower teeth part 123: Lower annular projection
123A; 1st terminal groove 123B: 2nd terminal groove
124: Inner support 124A: Joint space
125 : Joint Guide 200 : Flange
201: Flange body 202: Upper protrusion
203: Damper mounting part 204: Coupling projection
300: Damper plate 301: Circular body
302: Fastening part 302A: Fastening hole
303: Protruding guide B1: Upper bearing
B2: Lower bearing C: Coil
T1: 1st terminal terminal T2: 2nd terminal terminal

Claims (9)

A stator core (10) including a core base (101) having a cylindrical shape, a plurality of teeth (102) formed radially at regular intervals on the outer surface of the core base (101), and a central cylindrical body (103) positioned on the inner side of the core base (101) and having a central joining hole (103A) formed on the inner side; and
An upper insulator (11) coupled to the upper portion of the stator core (10);
Including,
A stator assembly of a blower motor, characterized in that the upper insulator (11) comprises an upper base (111) positioned on the upper side of the core base (101), an upper tooth portion (112) for covering and insulating the upper side of the teeth (102), and an upper central space (114A) and a second annular protrusion (114) positioned on the upper side of the central cylinder (103), wherein an upper bearing (B1) is inserted into the upper central space (114A). A stator assembly of a blower motor, characterized in that in the first paragraph, the upper insulator (11) further includes a first annular protrusion (113) formed by protruding upward from the upper base (111). A blower motor stator assembly, characterized in that in the second paragraph, further comprises a plurality of flow paths (116) formed between the first annular protrusion (113) and the second annular protrusion (114) located at the upper portion of the central cylinder (103). In the third paragraph, a blower motor stator assembly characterized in that it further includes a plurality of connecting ribs (115) connecting the first annular protrusion (113) and the second annular protrusion (114). A stator assembly of a blower motor, characterized in that in the first paragraph, the stator core (10) further includes a plurality of ribs (104) connecting the outer circumference of the core base (101) and the inner circumference of the central cylinder, and a plurality of through holes (105) formed in the space between the core base (101) and the central cylinder (103). A blower motor stator assembly, characterized in that in the second paragraph, the outer surface of the first annular protrusion (113) has a plurality of coil guides (117) formed by protruding radially at regular intervals. A stator core (10) including a core base (101) having a cylindrical shape, a plurality of teeth (102) formed radially at regular intervals on the outer surface of the core base (101), and a central cylindrical body (103) positioned on the inner side of the core base (101) and having a central joining hole (103A) formed on the inner side; and
An upper insulator (11) coupled to the upper portion of the stator core (10);
Including,
The upper insulator (11) includes an upper base (111) positioned on the upper side of the core base (101), an upper tooth portion (112) for covering and insulating the upper side of the tooth (102), a first annular protrusion (113) formed by protruding upward from the upper base (111), and a second annular protrusion (114) having an upper central space (114A) and positioned on the upper side of the central cylinder (103).
A stator assembly of a blower motor, characterized in that it further includes a plurality of paths (116) formed between the first annular protrusion (113) and the second annular protrusion (114). In the seventh paragraph, a blower motor stator assembly characterized in that it further includes a plurality of connecting ribs (115) connecting the first annular protrusion (113) and the second annular protrusion (114). A blower motor stator assembly, characterized in that in claim 7, the outer surface of the first annular protrusion (113) has a plurality of coil guides (117) formed to protrude radially at regular intervals.

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