CN111033975A - Motor with a stator having a stator core - Google Patents

Abstract

The motor has: a motor main body having a rotor that rotates about a central axis extending in a vertical direction, and a stator located radially outward of the rotor; a circuit board located on the upper side of the motor main body and extending in a direction perpendicular to the central axis; and a heat sink which is located below the circuit board and is in direct or indirect contact with the circuit board, the circuit board including: a substrate main body; and a 1 st heating element mounted on a lower surface of the substrate main body, the heat sink having: a heat sink main body portion extending along the circuit board; a motor body housing section that houses the motor body; and an element housing portion that houses the 1 st heating element, the motor main body housing portion and the element housing portion extending from the radiator main body portion toward a lower side, respectively, the radiator main body portion being provided with a rib that is located between the motor main body housing portion and the element housing portion.

Description

Motor with a stator having a stator core

Technical Field

The present invention relates to a motor.

Background

An electromechanical motor having a circuit board for controlling a motor main body is known to be provided with a heat sink for cooling the circuit board. Patent document 1 discloses that a stepped housing portion for housing a capacitor as a mounting component of a circuit board is provided in a heat sink.

Documents of the prior art

Patent document

Patent document 1: japanese patent laid-open publication No. 2013-062959

Disclosure of Invention

Problems to be solved by the invention

The conventional heat sink has a problem of low function of radiating heat absorbed from the circuit board and its mounting components to the outside.

In view of the above problems, an object of one embodiment of the present invention is to provide a motor having an improved heat dissipation effect of a heat sink.

Means for solving the problems

A motor according to one embodiment of the present invention includes: a motor main body having a rotor that rotates about a central axis extending in a vertical direction, and a stator that is located radially outside the rotor; a circuit board located on an upper side of the motor main body and extending in a direction perpendicular to the central axis; and a heat sink which is located below the circuit board and is in direct or indirect contact with the circuit board, the circuit board including: a substrate main body; and a 1 st heating element mounted on a lower surface of the substrate main body, the heat sink including: a heat sink main body portion extending along the circuit board; a motor body housing section that houses the motor body; and a component housing portion that houses the 1 st heat generating component, the motor body housing portion and the component housing portion each extending from the radiator main body portion toward a lower side, a rib being provided on the radiator main body portion, the rib being located between the motor body housing portion and the component housing portion.

Effects of the invention

According to one embodiment of the present invention, a motor having an improved heat dissipation effect of a heat sink is provided.

Drawings

Fig. 1 is a perspective view of a motor according to an embodiment.

Fig. 2 is a sectional view of the motor along line II-II of fig. 1.

Fig. 3 is a sectional view of the motor along the line III-III of fig. 1.

Fig. 4 is a bottom view of the motor as viewed from the lower side.

Detailed Description

Hereinafter, a motor 1 according to an embodiment of the present invention will be described with reference to the drawings. The scope of the present invention is not limited to the following embodiments, and can be arbitrarily changed within the scope of the technical idea of the present invention. In the drawings below, in order to facilitate understanding of each structure, the actual structure may be different from the scale, the number, or the like of each structure.

In the drawings, an XYZ coordinate system is appropriately shown as a three-dimensional orthogonal coordinate system. In the XYZ coordinate system, the Z-axis direction is a direction parallel to the axial direction of the central axis J described later. The X-axis direction is a direction perpendicular to the Z-axis direction. The Y-axis direction is a direction perpendicular to both the X-axis direction and the Z-axis direction.

In the following description, the positive side (+ Z side) in the Z-axis direction is referred to as "upper side", and the negative side (-Z side) in the Z-axis direction is referred to as "lower side". The upper and lower sides are only names for explanation, and do not limit the actual positional relationship and direction. Unless otherwise specified, a direction parallel to the central axis J (Z-axis direction) is simply referred to as "axial direction", a radial direction about the central axis J is simply referred to as "radial direction", and a circumferential direction about the central axis J, that is, a direction around the central axis J is simply referred to as "circumferential direction". In the following description, the term "plan view" refers to a state viewed from the axial direction.

[ Motor ]

Fig. 1 is a perspective view of a motor 1 according to the present embodiment. Fig. 2 is a sectional view of the motor 1 taken along line II-II of fig. 1. Fig. 3 is a sectional view of the motor 1 taken along line III-III of fig. 1. Fig. 4 is a bottom view of the motor 1 as viewed from below.

As shown in fig. 2, the motor 1 includes a motor main body 2, an upper bearing (bearing) 7A, a lower bearing 7B, a bearing holder 30, a circuit board 60, a case (heat sink, 1 st heat sink) 50, an upper heat sink (2 nd heat sink) 80, and a lid 40.

[ Motor subject ]

The motor main body 2 has a rotor 20 and a stator 25. The rotor 20 rotates about a central axis J extending in the vertical direction (axial direction). Rotor 20 includes shaft 21, rotor core 22, and rotor magnet 23. The shaft 21 extends along the central axis J. The shaft 21 is supported by the upper bearing 7A and the lower bearing 7B so as to be rotatable about the center axis J. Rotor core 22 is fixed to shaft 21. Rotor core 22 circumferentially surrounds shaft 21. Rotor magnet 23 is fixed to rotor core 22. More specifically, the rotor magnet 23 is fixed to an outer surface of the rotor core 22 along the circumferential direction. The rotor core 22 and the rotor magnet 23 rotate together with the shaft 21.

The stator 25 is located radially outside the rotor 20. The stator 25 is opposed to the rotor 20 with a gap therebetween in the radial direction, and surrounds the rotor 20 on the radially outer side. The stator 25 has a stator core 27, an insulator 28, and a coil 29.

The insulating member 28 is made of an insulating material. The insulator 28 covers at least a part of the stator core 27. When the motor 1 is driven, the coil 29 excites the stator core 27. The coil 29 is formed by winding a coil wire (not shown). The coil wire is wound around the teeth of the stator core 27 via an insulator 28. The coil wire is drawn upward at its end and is connected to the circuit board 60 through a through hole provided in the bearing holder 30. When a bus bar is provided between the motor main body 2 and the bearing holder 30, the end of the coil wire is connected to the bus bar, and the bus bar is connected to the circuit board 60.

[ Upper and lower side Bearings ]

The upper bearing 7A rotatably supports the upper end portion of the shaft 21. The upper bearing 7A is located on the upper side of the stator 25. The upper bearing 7A is supported by a bearing holder 30. The lower bearing 7B rotatably supports the lower end portion of the shaft 21. The lower bearing 7B is located on the lower side of the stator 25. The lower bearing 7B is supported by the lower bearing holding portion 54c of the housing 50.

In the present embodiment, the upper bearing 7A and the lower bearing 7B are ball bearings. However, the types of the upper bearing 7A and the lower bearing 7B are not particularly limited, and may be other types of bearings.

[ HOUSING (RADIATOR, RADIATOR 1 ]

The housing 50 is located on the lower side of the circuit substrate 60. The case 50 of the present embodiment directly contacts the circuit board 60, and functions as a heat sink for cooling the circuit board 60. The case 50 may be in indirect contact with the circuit board 60 as long as it is in thermal contact with the circuit board 60 and cools the circuit board 60. More specifically, the case 50 may be in contact with the circuit board 60 via a heat dissipating material such as heat dissipating grease.

The housing 50 includes a heat sink portion (heat sink main body portion) 53, a motor main body housing portion 54, and an element housing portion 55. The case 50 absorbs heat mainly generated by the circuit board 60 in the heat sink portion 53. The housing 50 accommodates the motor main body 2 in the motor main body accommodating portion 54. In the case 50, the element housing portion 55 houses a capacitor (1 st heat generating element) 65 provided on the circuit board 60.

The housing 50 is constructed as a single component. That is, the case 50 functions as a heat sink, a function of housing the motor main body 2, and a function of housing the capacitor 65 in a single component. The housing 50 may be a separate member in which at least 1 of the heat sink 53, the motor body housing 54, and the element housing 55 is fastened by fastening means such as screws. The heat sink 53 and the motor body housing 54 may be separate members, and the heat sink 53 may be a part of the bearing holder 30. However, since the case 50 is a single component, heat of the circuit board 60 absorbed by the heat sink 53 can be efficiently dissipated not only in the heat sink 53 but also in the motor main body housing 54 and the element housing 55. That is, according to the present embodiment, since the case 50 is configured as a single member, the heat radiation effect of the case 50 is improved. In addition, according to the present embodiment, since the housing 50 is formed of a single member, the assembly process of the motor 1 can be simplified.

The case 50 is made of a metal material having high heat dissipation characteristics and sufficient rigidity. For example, the case 50 is made of aluminum alloy. In this case, the housing 50 is manufactured by forming a rough shape by die casting or the like and then cutting a surface requiring precision.

The heat sink portion 53 extends in a direction perpendicular to the center axis J. The heat sink 53 is located below the circuit board 60. The heat sink 53 extends along the circuit board 60 below the circuit board 60. The heat sink 53 is located between the motor body housing 54 and the element housing 55 in a plan view, and connects the motor body housing 54 and the element housing 55. The heat sink 53 has an upper surface 53a facing upward and a lower surface 53b facing downward.

A heat radiation surface 53c is provided on the upper surface 53a of the heat sink 53, and the heat radiation surface 53c is in direct contact with the lower surface 61c of the substrate main body 61 of the circuit board 60 or indirectly via a member such as a heat sink. That is, the heat sink 53 has a heat radiation surface 53c that contacts the substrate main body 61. The heat sink 53 absorbs heat from the circuit board 60 on the heat radiating surface 53c, and cools the circuit board 60.

As will be described later, the circuit board 60 includes a plurality of field effect transistors (2 nd heating elements) 66 mounted on the upper surface 61d of the board main body 61. The field effect transistor 66 is also referred to as fet (field effect transistor). The field effect transistor 66 is a heat generating element that easily generates heat on the circuit substrate 60. At least a part of the field effect transistor 66 overlaps with the heat dissipation surface 53c when viewed from the axial direction. This enables heat generated by the field effect transistor 66 to efficiently move to the heat sink 53 on the heat radiating surface 53 c. This can suppress an excessive temperature rise of the field effect transistor 66, and improve the reliability of the operation of the field effect transistor 66.

In the present embodiment, a case where the heat generating element overlapping the heat radiating surface 53c in the axial direction is the field effect transistor 66 is exemplified. However, the heat generating element overlapping the heat radiating surface 53c may be another mounting member (element). In the present specification, the heat generating element refers to an element that generates heat and becomes high temperature during operation in the mounting member. As the heat generating element, a driver integrated circuit for driving a field effect transistor and a power supply integrated circuit are exemplified in addition to a field effect transistor and a capacitor, but the type is not limited as long as the element becomes a high temperature.

As shown in fig. 4, the heat sink 53 is provided with a rib 56. The rib 56 protrudes downward from the lower surface 53b of the heat sink 53. The rib 56 is located between the motor body housing portion 54 and the element housing portion 55. By providing the ribs 56 in the heat sink 53, the surface area of the heat sink 53 is increased. This can improve the heat radiation effect of the heat sink 53. In addition, by providing the ribs 56 in the heat sink portion 53, the rigidity of the heat sink portion 53 can be improved in the direction in which the ribs 56 extend. This can suppress deformation of the heat sink 53 due to external stress, thermal expansion, and thermal contraction. In particular, according to the present embodiment, the rib 56 is located between the motor body housing portion 54 and the element housing portion 55. Therefore, deformation of the heat sink portion 53, which changes the relative positional relationship between the motor body housing portion 54 and the element housing portion 55, can be suppressed.

As shown in fig. 2, the rib 56 is located immediately below the heat dissipation surface 53c that is in contact with the substrate main body 61. That is, at least a part of the rib 56 overlaps the heat radiation surface 53c when viewed from the axial direction. This can increase the heat capacity of the heat sink 53 directly below the heat radiating surface 53c, and can efficiently move heat from the substrate main body 61 to the heat sink 53 on the heat radiating surface 53 c. In addition, the heat that is absorbed from the circuit board 60 on the heat radiating surface 53c and moves to the heat sink portion 53 can be efficiently radiated by the rib 56.

As shown in fig. 4, the rib 56 includes a 1 st rib portion 56a and a 2 nd rib portion 56 b. The 1 st rib 56a extends in the radial direction (X-axis direction in the present embodiment) of the motor body housing 54. The 1 st rib 56a connects the motor body housing portion 54 and the element housing portion 55. The 2 nd rib 56b is connected to the 1 st rib 56 a. The 2 nd rib 56b extends in a direction perpendicular to the 1 st rib 56 a. The 2 nd rib 56b extends to intersect with the 1 st rib 56 a. In the present embodiment, the heat sink 53 is provided with 32 nd ribs 56 b.

According to the present embodiment, the 1 st rib 56a extends between and connects the motor body housing portion 54 and the element housing portion 55. Therefore, the rigidity of the heat sink portion 53 can be increased in the direction in which the motor body housing portion 54 and the element housing portion 55 are aligned. As a result, deformation of the heat sink portion 53, which changes the relative positional relationship between the motor body housing portion 54 and the element housing portion 55, can be effectively suppressed.

According to the present embodiment, the surface area of the heat sink 53 can be further increased by providing the 2 nd rib 56b in addition to the 1 st rib 56 a. Further, since the 2 nd rib 56b intersects the 1 st rib 56a perpendicularly, the rigidity of the heat sink 53 can be improved in the direction perpendicular to the 1 st rib 56 a. Preferably, the rib 56 includes 3 or more 2 nd rib portions 56 b. By providing 3 or more second ribs 56b, the rigidity of the heat sink 53 can be sufficiently improved.

As shown in fig. 4, the 2 nd rib 56b becomes narrower in width as it goes away from the 1 st rib 56a side. In other words, the 2 nd rib 56b is thicker on the 1 st rib 56a side. Therefore, according to the 2 nd rib 56b of the present embodiment, the rigidity of the heat sink 53 can be improved while suppressing an increase in weight as compared with a rib having an equal volume and extending with a uniform width.

As shown in fig. 2, the motor main body housing portion 54 has a cylindrical shape that is open to the upper side (+ Z side). The motor body housing portion 54 extends downward from the heat sink portion 53. The motor body housing portion 54 houses the rotor 20 and the stator 25. The motor main body housing portion 54 has a cylindrical portion 54a, a bottom portion 54b, and a lower bearing holding portion 54 c. The motor main body housing portion 54 may be a cylindrical member without the bottom portion 54 b. In this case, a bearing holder for holding a bearing is separately attached to the opening on the lower side of the motor body housing portion 54.

The cylindrical portion 54a surrounds the stator 25 from the radially outer side. In the present embodiment, the cylindrical portion 54a is cylindrical. The stator core 27 and the bearing holder 30 are fixed to the inner peripheral surface of the cylindrical portion 54 a. A radiator portion 53 is connected to an upper end portion of the cylindrical portion 54a and to an outer peripheral surface of the cylindrical portion 54 a.

The bottom portion 54b is located at the lower end of the cylindrical portion 54 a. The bottom portion 54b is located on the lower side of the stator 25. The lower bearing holding portion 54c is located at the center of the bottom portion 54b in plan view. The lower bearing holding portion 54c holds the lower bearing 7B. A hole 54d penetrating in the axial direction is provided at the center of the lower bearing holder 54c in a plan view. The lower end of the shaft 21 is inserted into the hole 54 d.

The element housing portion 55 is open to the upper side (+ Z side). The element housing portion 55 extends downward from the heat sink portion 53. As shown in fig. 4, the element housing section 55 of the present embodiment houses 3 capacitors 65. The 3 capacitors 65 are arranged in one direction (Y-axis direction in the present embodiment) perpendicular to the central axis J. In the present embodiment, the direction in which the 3 capacitors 65 are arranged coincides with the direction in which the 2 nd rib 56b extends. In a plan view, element housing portion 55 has a longitudinal direction defined by a direction in which 3 capacitors 65 are arranged (i.e., a direction in which 2 nd rib 56b extends). The dimension S1 in the longitudinal direction of the element housing portion 55 is smaller than the diameter D of the motor body housing portion 54. That is, even when the plurality of capacitors 65 are arranged in a row in one direction, the dimension S1 in the longitudinal direction of the element housing portion 55 does not exceed the motor main body housing portion 54. Therefore, the size of the motor 1 can be suppressed in the direction perpendicular to the central axis J.

As shown in fig. 2, the capacitor 65 has a top surface 65b facing downward and a side surface 65a facing in a direction perpendicular to the axial direction. The element housing portion 55 includes: a sidewall portion 55a surrounding a side surface 65a of the capacitor 65; and a housing bottom portion 55b located below the capacitor 65 and axially opposed to the top surface 65b of the capacitor 65.

According to the present embodiment, the case 50 has the element housing portion 55 housing the capacitor 65. The capacitor 65 is a heat generating element that easily generates heat on the circuit board 60. Therefore, heat generated in capacitor 65 can be efficiently absorbed in element housing portion 55. Further, a heat dissipating material such as heat dissipating grease is preferably accommodated between the side wall portion 55a of the element accommodating portion 55 and the side surface 65a of the capacitor 65. This enables heat to be efficiently transferred from side surface 65a of capacitor 65 toward element housing portion 55, thereby improving the reliability of the operation of capacitor 65. Further, a heat dissipation material may be disposed between the housing bottom portion 55b of the element housing portion 55 and the top surface 65b of the capacitor 65. However, there are cases where an explosion-proof valve is usually provided on the top surface 65b of the capacitor 65. In this case, the heat dissipating material is disposed so as to avoid at least the explosion-proof valve.

The element housing portion 55 may be configured to be open to the lower side without the housing bottom portion 55 b. Further, a part of the side wall portion 55a of the element housing portion 55 may be opened in the horizontal direction. That is, the housing bottom portion 55b and the side wall portion 55a may not necessarily surround the top surface 65b and the side surface 65a of the capacitor 65 over the entire range.

In the present embodiment, the motor body housing portion 54 and the element housing portion 55 each extend downward from the heat sink portion 53. That is, the motor body housing portion 54 and the element housing portion 55 are separated from each other when viewed from the axial direction. According to the present embodiment, since the motor body housing portion 54 and the element housing portion 55 extend from the heat sink portion 53, respectively, the surface area of the outer peripheral surface of the case 50 is increased, and the heat radiation effect of the case 50 can be improved. As described above, the motor main body housing portion 54 and the element housing portion 55 may be different members fixed to each other via the heat sink portion 53.

The housing 50 has an upper surface 50a facing the upper side. The upper surface 50a is provided across the motor body housing portion 54, the element housing portion 55, and the heat sink portion 53 of the housing 50. The upper surface 50a is opposed to the lid 40. The upper surface 50a is provided with a 2 nd groove portion 52 extending along an outer edge of the upper surface 50 a. The 2 nd groove portion 52 is recessed downward with respect to the upper surface 50 a. The 2 nd groove portion 52 extends with a uniform width and a uniform depth in a plane perpendicular to the center axis J. The 2 nd groove portion 52 accommodates the 2 nd projecting portion 42 of the cover portion 40 described later.

[ Bearings-holder ]

The bearing holder 30 is located on the upper side (+ Z side) of the stator 25. The bearing holder 30 supports the upper bearing 7A. The bearing holder 30 has a circular shape in plan view, for example, concentric with the central axis J. The bearing holder 30 is positioned in the opening 54e on the upper side of the motor body housing 54, and is fixed to the inner peripheral surface of the motor body housing 54.

The bearing holder 30 includes: an annular disc-shaped holder body portion 31; an upper bearing holding portion 32 located radially inward of the holder body portion 31; and a holder fixing portion 33 located radially outward of the holder body portion 31.

The upper bearing holding portion 32 holds the upper bearing 7A. The upper bearing holding portion 32 is located at the center of the bearing holder 30 in a plan view. A hole 32a penetrating in the axial direction is provided at the center of the upper bearing holder 32 in a plan view. The upper end of the shaft 21 is inserted into the hole 32 a. The holder fixing portion 33 has a cylindrical shape protruding in the vertical direction from the radial outer edge of the holder body portion 31. The outer peripheral surface of the holder fixing portion 33 is radially opposed to the inner peripheral surface of the motor body housing portion 54. The holder fixing portion 33 is fitted and fixed to the inner peripheral surface of the motor body housing portion 54.

At least a part of the bearing holder 30 overlaps the heat sink portion 53 of the housing 50 in the axial direction. Therefore, the space above the bearing holder 30 can be sufficiently enlarged. As a result, the degree of freedom in the arrangement of the circuit board 60 positioned above the bearing holder 30 and the arrangement of the mounting components of the circuit board 60 can be improved.

[ Circuit Board ]

The circuit board 60 is located above the motor main body 2 and the bearing holder 30. The circuit substrate 60 extends in a direction perpendicular to the central axis J (i.e., a direction perpendicular to the up-down direction). A coil wire extending from the coil 29 of the stator 25 is connected to the circuit board 60. The circuit board 60 controls the rotation of the rotor 20 by flowing a current through the coil 29.

The circuit board 60 includes a substrate main body 61, a plurality of (3 in the present embodiment) capacitors (1 st heating element) 65, and a plurality of field effect transistors (2 nd heating element) 66. In addition, the substrate main body 61 includes electronic components (not shown) for controlling the rotation of the rotor 20.

The substrate main body 61 is disposed so as to be perpendicular to the axial direction (i.e., the vertical direction). The substrate main body 61 has an upper surface 61d facing upward and a lower surface 61c facing downward. Further, the substrate main body 61 includes: an overlapping portion 61A that overlaps the motor main body 2 when viewed from the top-bottom direction; and a protruding portion 61B located outside the motor main body 2 when viewed from the up-down direction.

The capacitor 65 is mounted on the lower surface 61c of the substrate body 61. The capacitor 65 has a cylindrical shape extending in the axial direction. The capacitor 65 has: a top surface 65b located on the opposite side from the substrate main body 61 and facing the lower side; and a side surface 65a facing in a direction perpendicular to the axial direction (vertical direction). Among the components mounted on the circuit board 60, the capacitor 65 has the largest dimension in the axial direction (vertical direction). The field effect transistor 66 is mounted on the upper surface 61d of the substrate main body 61. The field effect transistor 66 has a rectangular shape in plan view. On one or both of the upper surface 61d and the lower surface 61c of the substrate main body 61, electronic components such as a rotation sensor and a choke coil are mounted in addition to the capacitor 65 and the field effect transistor 66.

The capacitor 65 and the field effect transistor 66 as the heat generating element are mounted on the extension portion 61B of the substrate main body 61. An upper heat sink 80 described later is located on the upper side of the protruding portion 61B. The upper heat sink 80 is in direct or indirect contact with the protruding portion 61B and the field effect transistor 66 mounted on the upper surface 61d of the protruding portion 61B, and cools them. In addition, the heat sink portion 53 and the element housing portion 55 of the case 50 are located below the protruding portion 61B. The heat sink 53 and the element housing 55 are in direct or indirect contact with the extension 61B and the capacitor 65 attached to the lower surface 61c of the extension 61B, and cool them. That is, according to the present embodiment, the extension portion 61B on which the heating element (the capacitor 65 and the field effect transistor 66) is mounted is sandwiched between the upper heat sink 80 and the case 50 from the up-down direction. This enables the upper heat sink 80 and the case 50 to more effectively cool the heating elements 65 and 66 attached to the extension portion 61B. Further, according to the present embodiment, by disposing the heater elements 65 and 66 to be cooled in the extension portion 61B of the substrate main body 61, the structure required for cooling the heater elements 65 and 66 can be disposed offset from the motor main body 2 in a plan view. Therefore, the axial dimension (vertical dimension) of the motor 1 can be reduced.

[ Upper radiator (2 nd radiator) ]

The upper heat sink 80 is located on the upper side of the circuit substrate 60. The upper heat sink 80 covers a part of the circuit substrate 60 from the upper side. The upper heat sink 80 of the present embodiment is in direct or indirect contact with the circuit board 60, and functions as an upper heat sink for cooling the circuit board 60. The upper heat sink 80 may be in direct contact with the circuit board 60 or may be in indirect contact therewith, as long as it is in thermal contact with the circuit board 60 and cools the circuit board 60. More specifically, the upper heat sink 80 may be in contact with the circuit board 60 via a heat dissipating material such as heat dissipating grease.

The upper heat sink 80 has a heat absorbing portion 85 and fins 89a on an upper surface 85a of the heat absorbing portion 85. The upper heat sink 80 is made of a metal material (e.g., an aluminum alloy or a copper alloy) having high heat dissipation characteristics.

As shown in fig. 3, the heat absorbing portion 85 has an upper surface 85a facing upward and a lower surface 85b facing downward. In addition, the heat absorbing portion 85 is provided with a pair of screw insertion holes 85 c. The screw insertion hole 85c penetrates the heat absorbing portion 85 in the axial direction. Fixing screws 88 are inserted into the pair of screw insertion holes 85c, respectively. The fixing screw 88 is screwed to the heat sink portion 53 of the housing 50. Thereby, the lower surface 85b of the heat absorbing portion 85 abuts the upper surface 53a of the heat sink portion 53, and the upper heat sink 80 is fixed to the case 50.

According to the present embodiment, the upper heat sink 80 is directly in contact with the case 50 and fixed to each other. The upper heat sink 80 and the case 50 respectively absorb heat from the circuit substrate 60. By bringing the upper heat sink 80 and the case 50 into contact and fixing with each other, thermal movement is generated between the upper heat sink 80 and the case 50. Therefore, even when one of the upper heat sink 80 and the case 50 becomes high in temperature, the heat can be transferred to the other side and radiated from the other side. This improves the heat dissipation efficiency, and as a result, the cooling effect of the circuit board 60 can be improved.

A recess 86 is provided on a lower surface 85b of the heat absorbing portion 85. The field effect transistor 66 of the circuit board 60 is disposed in the recess 86. The recess 86 is filled with a heat dissipating material such as heat dissipating grease, for example, so that heat generated by the field effect transistor 66 is efficiently transferred to the heat absorbing portion 85. That is, according to the present embodiment, the heat dissipation material is filled in the recess 86 in which the field effect transistor 66 as the heat generating element is housed, whereby the field effect transistor 66 can be cooled efficiently. In addition, when the heat dissipating material is a fluid heat dissipating grease, leakage of the heat dissipating grease from the recess 86 can be suppressed.

As will be described later, the lid 40 is provided above the upper heat sink 80. The lid 40 is provided with an opening 49 penetrating in the vertical direction. The upper heat sink 80 has an exposed portion 89 exposed from the opening portion 49 of the cover 40. The exposed portion 89 is located on the upper surface 85a of the heat sink 85.

According to the present embodiment, the upper heat sink 80 has the exposed portion 89, and therefore the upper heat sink 80 can efficiently dissipate heat absorbed from the circuit board 60 to the outside of the motor 1 from the exposed portion 89. This can improve the cooling efficiency of the circuit board 60 by the upper heat sink 80.

The exposed portion 89 of the upper heat sink 80 is located directly above the field effect transistor 66 as a heat generating element. That is, when viewed from the axial direction (vertical direction), the exposed portion 89 of the upper heat sink 80 overlaps at least a part of the field effect transistor 66. This allows the exposed portion 89 to effectively dissipate heat transferred from the circuit board 60 to the upper heat sink 80. The heating element overlapping the exposed portion 89 when viewed in the axial direction may be a heating element other than the field-effect transistor 66 (for example, a capacitor, a driver integrated circuit for driving the field-effect transistor, and a power supply integrated circuit).

As shown in fig. 1, the fins 89a are located at the exposed portion 89 of the upper heat sink 80. The fins 89a protrude upward from the upper surface 85a of the heat absorbing portion 85. The fin 89a penetrates the opening 49 in the exposed portion 89.

The upper heat sink 80 is provided with a plurality of fins 89 a. The plurality of fins 89a extend in one direction perpendicular to the up-down direction. In the present embodiment, the fins 89a extend in the X-axis direction. According to the present embodiment, by providing the fins 89a in the exposed portion 89, the surface area of the exposed portion 89 can be increased, and the heat radiation efficiency of the upper heat sink 80 in the exposed portion 89 can be improved. Further, according to the present embodiment, since the plurality of fins 89a extend in one direction, when the motor 1 is disposed in the gas flowing in one direction, the fins 89a are disposed so as to extend in the flowing direction of the gas, and thus the heat radiation efficiency of the fins 89a can be improved.

In the present embodiment, the case where the upper heat sink 80 has the fins 89a is exemplified. However, if the upper heat sink 80 has the exposed portion 89, a certain effect of improving the heat radiation efficiency can be obtained even if the upper heat sink 80 does not have the fins 89 a.

The heat sink 85 has a top surface 85a provided with a 1 st groove portion 81, and the 1 st groove portion 81 surrounds the exposed portion 89 when viewed in the axial direction (vertical direction). The 1 st groove portion 81 extends with a uniform width and a uniform depth in a plane perpendicular to the center axis J. The 1 st groove portion 81 is recessed downward with respect to the upper surface 85 a. The 1 st projecting portion 41 of the cover portion 40 described later is housed in the 1 st groove portion 81.

[ COVER ]

As shown in fig. 2, the cover 40 is positioned above the case 50, the circuit board 60, and the upper heat sink 80. The lid portion 40 covers the upper surface 50a of the housing 50. The cover 40 covers the circuit board 60 from above to protect the circuit board 60. The cover 40 covers the opening of the motor main body housing 54 of the housing 50, and suppresses entry of contaminants into the rotating portion of the motor main body 2 and the like.

As shown in fig. 1, the cover 40 includes: a flat portion 45; an outer edge portion 46 located on the outer edge of the flat portion 45 and protruding downward with respect to the flat portion 45; and a connector portion 47 extending upward from the flat portion 45.

The connector portion 47 has a cylindrical shape extending upward from the flat portion 45. A connection terminal (not shown) extending upward from the circuit board 60 is provided inside the connector portion 47. The connection terminals are connected to an external device (not shown) that supplies power to the circuit board 60.

As shown in fig. 2, the flat portion 45 extends in a direction perpendicular to the axial direction (vertical direction). That is, the flat portion 45 extends along the circuit substrate 60. The flat portion 45 has an upper surface 45a facing upward and a lower surface 45b facing downward.

The flat portion 45 is provided with an opening 49. The opening 49 has a rectangular shape when viewed from the axial direction. The fins 89a of the upper heat sink 80 are inserted into the openings 49. The upper end of the fin 89a is located above the upper surface 45a of the flat portion 45.

The lower surface 45b of the flat portion 45 is axially separated from the heat absorbing portion 85. Therefore, the flat portion 45 does not contact the upper heat sink 80. The lower surface 45b of the flat portion 45 is provided with a 1 st projecting portion 41 projecting downward.

The 1 st projection 41 surrounds the opening 49 when viewed from the axial direction. The 1 st projection 41 extends with a uniform width and a uniform height in a plane perpendicular to the central axis J. The 1 st projection 41 is received in the 1 st groove 81, and the 1 st groove 81 is provided in the upper heat sink 80. The upper heat sink 80 is provided with an exposed portion 89 exposed from the opening portion 49. Therefore, when viewed from the axial direction (vertical direction), exposed portion 89 is surrounded by 1 st protruding portion 41 and 1 st groove portion 81. A gap is provided between the inner wall surface of the 1 st groove portion 81 and the 1 st convex portion 41. The 1 st groove portion 81 is filled with an adhesive B.

According to the present embodiment, the 1 st protruding portion 41 is housed in the 1 st groove portion 81 filled with the adhesive B. Further, since the 1 st protruding portion 41 and the 1 st groove portion 81 surround the exposed portion 89, water and contaminants can be suppressed from entering the motor 1 from the opening portion 49 of the cover 40. This can improve the dust-proof performance and the water-proof performance of the motor 1.

In the present embodiment, the 1 st groove part 81 is filled with the adhesive B, and the adhesive B closes the gap between the inner wall surface of the 1 st groove part 81 and the 1 st convex part 41. Therefore, the intrusion of contaminants can be more effectively suppressed. However, even when the filler such as the adhesive B is not filled, the 1 st projecting portion 41 is inserted into the 1 st groove portion 81, so that a labyrinth structure can be formed in the contaminant invasion path, and the invasion of the contaminant can be suppressed.

In the present embodiment, the configuration in which the 1 st groove portion 81 is provided in the upper heat sink 80 and the 1 st projection portion 41 is provided in the lid portion 40 is exemplified. However, 1 st protruding portion 41 and 1 st recessed portion 81 may be provided on the opposite sides of upper heat sink 80 and lid 40, respectively, as long as they surround exposure portion 89. That is, the 1 st protruding portion 41 protruding toward the other side may be provided on one of the lid portion 40 and the upper heat sink 80, and the 1 st groove portion 81 accommodating the 1 st protruding portion 41 may be provided on the other.

According to the present embodiment, the adhesive B is filled between the inner wall surface of the 1 st groove part 81 and the 1 st convex part 41. Thereby, the cover 40 and the upper heat sink 80 can be fixed to each other around the exposed portion 89. Further, since the adhesive B is filled in the 1 st groove portion 81, the adhesive B can be provided in a uniform amount in the circumferential direction, and stable adhesion strength against stress from each direction can be easily achieved.

According to the present embodiment, a gap is provided between the inner wall surface of the 1 st groove portion 81 and the 1 st convex portion 41. Therefore, the inner wall surface of the 1 st groove portion 81 and the 1 st projecting portion 41 do not directly contact in the up-down direction and the horizontal direction. Therefore, the positioning of the cover 40 with respect to the upper heat sink 80 in the vertical direction and the horizontal direction can be performed at other portions. Specifically, the cover 40 and the upper heat sink 80 can be brought into contact with the case 50, respectively, and the cover 40 and the upper heat sink 80 can be positioned with respect to the case 50, respectively. Therefore, in another member (the housing 50 of the present embodiment) in which management of the dimensional accuracy and the surface accuracy is easy, the dimensions of each part can be managed.

According to the present embodiment, since the lower surface 45B of the flat portion 45 is axially separated from the heat absorbing portion 85, the adhesive B filled in the 1 st groove portion 81 is exposed to the outside air. This can promote curing of the adhesive B filled in the 1 st groove portion 81. In the step of housing the 1 st protruding portion 41 in the 1 st groove portion 81, the excess adhesive B that has overflowed from the 1 st groove portion 81 can escape to the outside of the 1 st groove portion 81.

The outer edge 46 protrudes downward from the outer edge of the flat portion 45. The outer edge portion 46 surrounds the flat portion 45 over the entire circumference when viewed from the axial direction. The 2 nd projection 42, the inner lower end surface 46a, and the outer lower end surface 46b are provided at the lower end of the outer edge 46.

The 2 nd convex portion 42 protrudes downward. The 2 nd protrusion 42 extends with a uniform width and a uniform height in a plane perpendicular to the central axis J. The 2 nd protrusion 42 extends over the entire outer edge 46. Therefore, the 2 nd convex portion 42 surrounds the flat portion 45 over the entire circumferential range when viewed from the axial direction.

The 2 nd convex portion 42 is received in the 2 nd groove portion 52, and the 2 nd groove portion 52 is provided in the housing 50. The 2 nd projecting portion 42 and the 2 nd groove portion 52 surround the 1 st projecting portion 41 and the 1 st groove portion 81 from the outside when viewed from the axial direction. A gap is provided between the inner wall surface of the 2 nd groove portion 52 and the 2 nd projecting portion 42. The 2 nd groove portion 52 is filled with an adhesive B.

According to the present embodiment, the 2 nd protrusion 42 is housed in the 2 nd groove portion 52 filled with the adhesive B. Further, since the 2 nd convex portion 42 and the 2 nd groove portion 52 surround the 1 st convex portion 41 and the 1 st groove portion 81 from the outside when viewed from the axial direction, water and contaminants can be suppressed from entering the inside of the motor 1 from between the cover portion 40 and the housing 50 even at a position outside the 1 st convex portion 41 and the 1 st groove portion 81. This can improve the dust-proof performance and the water-proof performance of the motor 1.

In the present embodiment, the 2 nd groove portion 52 is filled with the adhesive B, and the adhesive B closes the gap between the inner wall surface of the 2 nd groove portion 52 and the 2 nd projecting portion 42. Therefore, the intrusion of contaminants can be more effectively suppressed. However, even when the filler such as the adhesive B is not filled, the 2 nd projecting portion 42 is inserted into the 2 nd groove portion 52, so that a labyrinth structure can be formed in the contaminant invasion path, and the invasion of the contaminant can be suppressed.

In the present embodiment, the case 50 is provided with the 2 nd groove 52, and the lid 40 is provided with the 2 nd projection 42. However, the 2 nd convex portion 42 and the 2 nd groove portion 52 may be provided on the opposite sides of the case 50 and the cover portion 40, respectively. That is, the 2 nd projecting portion 42 projecting toward the other side may be provided on one of the lid portion 40 and the case 50, and the 2 nd groove portion 52 accommodating the 2 nd projecting portion 42 may be provided on the other.

According to the present embodiment, the adhesive B is filled between the inner wall surface of the 2 nd recessed portion 52 and the 2 nd projecting portion 42. This enables the lid 40 to be fixed to the case 50 at the outer edge 46 of the lid 40. Further, since the 2 nd groove portion 52 is filled with the adhesive B, the adhesive B can be provided in a uniform amount in the circumferential direction, and stable bonding strength against stress from each direction can be easily achieved.

The inner lower end surface 46a is a surface facing downward. Inner lower end surface 46a is located inside the region surrounded by 2 nd projection 42 in plan view. The inner lower end surface 46a contacts the upper surface 50a of the housing 50. The lid 40 can be positioned in the axial direction (vertical direction) with respect to the housing 50 by bringing the inner lower end surface 46a into contact with the upper surface 50a of the housing 50.

The outer lower end surface 46b is a surface facing downward. Outer lower end surface 46b is located inside the region surrounded by 2 nd projection 42 in plan view. The outer lower end surface 46b is axially separated from the upper surface 50a of the housing 50. This allows the adhesive B filled in the 2 nd groove 52 to be exposed to the outside air, thereby promoting curing of the adhesive B. In the step of housing the 2 nd projecting portion 42 in the 2 nd groove 52, the adhesive B overflowing from the 2 nd groove 52 can be trapped in the gap between the outer lower end surface 46B and the upper surface 50a of the case 50. Therefore, when the filling amount of the adhesive B varies, the excess adhesive B can be made to escape into the gap between the outer lower end surface 46B and the upper surface 50a of the case 50. Further, by providing a gap between the outer lower end surface 46B and the upper surface 50a of the housing 50, the filling state, the cured state, and the like of the adhesive B can be visually confirmed. Therefore, the quality of the product on the production line is easily ensured.

In the present embodiment, as the adhesive B filled in the 1 st groove portion 81 and the 2 nd groove portion 52, a moisture-curable adhesive is preferably used. The moisture-curable adhesive is cured by moisture in the air. By using a moisture-curable adhesive as the adhesive B, deterioration of the adhesive due to moisture can be suppressed, and the reliability of waterproofing of the motor 1 can be improved.

Next, a process of assembling the lid 40 in the manufacturing process of the motor 1 will be described. In the present embodiment, the assembly of the lid 40 to the motor 1 is performed at the end of the assembly process.

First, the interiors of the 1 st groove portion 81 of the upper heat sink 80 and the 2 nd groove portion 52 of the case 50 are filled with the uncured adhesive B.

Next, the lid portion 40 is brought close to the upper heat sink 80 and the case 50 fixed to the upper heat sink 80 from the upper side, the 1 st protruding portion 41 is inserted into the 1 st groove portion 81, and the 2 nd protruding portion 42 is inserted into the 2 nd groove portion 52.

Subsequently, the adhesive B is cured.

The lid 40 is assembled to the motor 1 through the above steps.

According to the present embodiment, the 1 st projecting portion 41 and the 2 nd projecting portion 42 project in the same direction, and the 1 st groove portion 81 and the 2 nd groove portion 52 open in the same direction. In addition, the 1 st groove portion 81 and the 2 nd groove portion 52 are filled with uncured adhesive B. Since the 1 st groove portion 81 and the 2 nd groove portion 52 are opened in the same direction, the 1 st groove portion 81 and the 2 nd groove portion 52 can be simultaneously filled with the uncured adhesive B. In addition, the following steps can be adopted: after the uncured adhesive B is filled in the 1 st groove part 81 and the 2 nd groove part 52, the lid part 40 is lowered, and the 1 st protruding part 41 and the 2 nd protruding part 42 are accommodated in the 1 st groove part 81 and the 2 nd groove part 52, respectively. This can simplify the assembly process of the lid 40.

As shown in fig. 1, the case 50 and the lid 40 are fixed to each other by the engaging portion 6. The motor 1 is provided with a plurality of engaging portions 6 in the circumferential direction.

The engagement portion 6 is constituted by a hook portion 43 provided to the cover portion 40 and a pawl portion 58 provided to the housing 50. The hook portion 43 of the lid portion 40 extends downward in a U shape from the outer edge portion 46. The claw portion 58 protrudes outward in the horizontal direction from the outer side surface of the housing 50. In the process of assembling the lid portion 40, the worker brings the lid portion 40 close to the housing 50 in the axial direction, and thereby the claw portions 58 are fitted to the hook portions 43, and the lid portion 40 is fixed to the housing 50. In the present embodiment, the engagement portion 6 is provided to hold the cover 40 during a period from when the cover 40 is assembled to the housing 50 until the adhesive B is cured. When the adhesive B is not used for fixing the lid 40, the lid 40 is fixed to the housing 50 in a fixed manner by the fixing function of the engaging portion 6.

While the embodiment and the modification of the present invention have been described above, the configurations and combinations thereof in the embodiment and the modification are merely examples, and addition, omission, replacement, and other modifications of the configurations can be made within the scope not departing from the gist of the present invention. The present invention is not limited to the embodiments.

Description of the reference symbols

1: a motor; 2: a motor main body; 6: a fastening part; 7A: an upper side bearing (bearing); 20: a rotor; 21: a shaft; 25: a stator; 30: a bearing retainer; 40: a cover portion; 41: the 1 st convex part; 42: a 2 nd convex part; 49: an opening part; 50: a case (heat sink, 1 st heat sink); 52: a 2 nd groove part; 53: a radiator portion (radiator main body portion); 53 c: a heat dissipating surface; 54: a motor main body housing section; 54e, and (b) 54 e: an opening; 55: an element housing section; 56: a rib; 56 a: the 1 st rib part; 56 b: the 2 nd rib part; 60: a circuit substrate; 61: a substrate main body; 61A: an overlapping portion; 61B: a protruding portion; 65: a capacitor (1 st heating element, heating element); 66: a field effect transistor (2 nd heating element, heating element); 80: an upper radiator (2 nd radiator); 81: a 1 st groove part; 89: an exposed portion; 89 a: a fin; b: an adhesive; d: a diameter; j: a central axis; s1: and (4) size.

Claims (10)

1. A motor, comprising:

a motor main body having a rotor that rotates about a central axis extending in a vertical direction, and a stator that is located radially outside the rotor;

a circuit board located on an upper side of the motor main body and extending in a direction perpendicular to the central axis; and

a heat sink located on a lower side of the circuit substrate and in direct or indirect contact with the circuit substrate,

the circuit board includes:

a substrate main body; and

a 1 st heating element mounted on a lower surface of the substrate main body,

the heat sink has:

a heat sink main body portion extending along the circuit board;

a motor body housing section that houses the motor body; and

an element housing portion that houses the 1 st heat generating element,

the motor body receiving portion and the element receiving portion extend from the radiator main body portion toward a lower side,

a rib is provided on the radiator main body portion between the motor main body housing portion and the element housing portion.

2. The motor of claim 1,

the heat sink is constructed as a single component,

the rotor has a shaft extending along the central axis,

the motor has: a bearing rotatably supporting the shaft; and a bearing holder which supports the bearing,

the bearing holder is positioned at the opening of the upper side of the motor body receiving part,

at least a part of the bearing holder overlaps the radiator main body portion in the axial direction.

3. The motor according to claim 1 or 2,

the rib includes a 1 st rib portion extending in a radial direction connecting the motor body receiving portion with the element receiving portion.

4. The motor of claim 3,

the rib includes a 2 nd rib portion connected to the 1 st rib portion and extending in a direction perpendicular to the 1 st rib portion.

5. The motor of claim 4,

the 2 nd rib extends to intersect with the 1 st rib.

6. The motor according to claim 4 or 5,

the 2 nd rib is narrower in width as it is farther from the 1 st rib side.

7. The motor according to any one of claims 4 to 6,

the ribs include 3 or more of the 2 nd rib portions.

8. The motor according to any one of claims 4 to 7,

the element housing portion has a direction in which the 2 nd rib extends when viewed from the axial direction as a longitudinal direction,

the element housing portion has a length dimension smaller than a diameter of the motor body housing portion.

9. The motor according to any one of claims 1 to 8,

the circuit board has a 2 nd heating element, the 2 nd heating element is mounted on the upper surface of the board main body,

the heat sink main body portion has a heat radiation surface that contacts the lower surface of the substrate main body,

at least a part of the 2 nd heating element overlaps with the heat radiating surface when viewed from the axial direction.

10. The motor of claim 9,

at least a portion of the rib overlaps the heat radiating surface when viewed from the axial direction.

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