阅读说明：本技术 旋转电机 (Rotating electrical machine ) 是由 宫园秀明 于 2019-07-11 设计创作，主要内容包括：本发明提供一种旋转电机。在转子(12)的端面上直立设置圆环形状的转子侧周壁(52)。此外,在与转子(12)的端面对置的端罩(46)的内壁面上,以与转子侧周壁(52)接近的方式而直立设置圆弧形状的壳体侧周壁(56)。通过转子(12)的端面、端罩(46)的内壁面、转子侧周壁(52)及壳体侧周壁(56),从而形成接受并积存冷却液的冷却液积存部(58)。转子芯(24)具有在沿着旋转轴线(L)的方向上延伸并贯通的冷却液流道(36)。冷却液流道(36)以相对于冷却液积存部(58)而开口的方式被配置。从冷却液积存部(58)流至冷却液流道(36)的冷却液从内部对转子芯(24)进行冷却。(The invention provides a rotating electrical machine. An annular rotor-side peripheral wall (52) is provided upright on the end face of the rotor (12). A housing-side peripheral wall (56) having an arcuate shape is provided upright on the inner wall surface of the end cover (46) facing the end surface of the rotor (12) so as to be close to the rotor-side peripheral wall (52). A coolant reservoir (58) is formed by the end face of the rotor (12), the inner wall surface of the end cover (46), the rotor-side peripheral wall (52), and the case-side peripheral wall (56) and receives and retains coolant. The rotor core (24) has a coolant flow channel (36) that extends in the direction along the rotation axis (L) and penetrates therethrough. The coolant flow channel (36) is disposed so as to be open to the coolant reservoir (58). The coolant flowing from the coolant reservoir (58) to the coolant flow channel (36) cools the rotor core (24) from inside.)

1. A rotating electrical machine has:

a housing;

a rotor supported by the housing so as to be rotatable about a rotation axis;

a coolant reservoir that is located adjacent to a rotor end face of the rotor, stores coolant, and is formed by a first side face defined by the rotor end face, a second side face defined by a case inner wall face of the case facing the rotor end face, and a peripheral face defined by a case side peripheral wall and a rotor side peripheral wall, wherein the case side peripheral wall is provided upright on the case inner wall face and extends in a circumferential direction around the rotation axis, and the rotor side peripheral wall is provided upright on the rotor end face and extends over the entire circumference around the rotation axis,

and a coolant flow channel that extends in a direction along the rotation axis, penetrates the rotor, has one end that is disposed so as to be open to the coolant reservoir, and has the coolant flowing therethrough.

2. The rotating electric machine according to claim 1,

the rotor-side peripheral wall is located radially outward of the housing-side peripheral wall, and has an inward flange at a tip edge thereof, the inward flange extending radially inward and having a tip abutting an outer surface of the housing-side peripheral wall.

3. The rotating electric machine according to claim 1 or 2,

the rotor includes rotor core plates laminated in a direction along the rotation axis to form a rotor core, and end plates located at both ends of the laminated rotor core plates,

an end plate cooling hole that becomes a part of the coolant flow passage is formed in the end plate on the coolant reservoir side,

core plate cooling holes are formed in the rotor core plates, respectively, and the core plate cooling holes are formed as part of the coolant flow channels and are located at positions shifted radially outward from the end plate cooling holes.

Technical Field

The present disclosure relates to a rotary electric machine, and more particularly, to a cooling structure of a rotor.

Background

There are known an electric motor that converts electric energy into kinetic energy of rotation, a generator that converts kinetic energy of rotation into electric energy, and an electronic device that can function as both an electric motor and a generator. Hereinafter, these electronic devices are collectively referred to as a rotating electrical machine.

Patent document 1 discloses a motor that is cooled by oil. The engine oil is supplied to the motor (2) through the first oil passage (91) and the second oil passage (92). The first oil passage (91) includes a hollow shaft (21), and oil is supplied to a core through hole (24e) in the rotor core (24) via the shaft (21). The second oil passage (92) supplies oil to a reservoir (98) provided above the motor (2). Oil is supplied from a reservoir (98) to a coil end (31a) of a stator (30). The symbols in parentheses are those used in patent document 1 below, and are not related to the symbols used in the description of the embodiments of the present application.

Prior art documents

Patent document

Patent document 1: japanese patent laid-open publication No. 2018-27003

Disclosure of Invention

Due to the structure of the rotating electrical machine, particularly the structure of the output shaft of the rotating electrical machine and the periphery thereof, it may be impossible to supply a coolant such as an engine oil to the inside of the rotor through the output shaft.

The present disclosure aims to supply a coolant to the inside of a rotor without passing through an output shaft of a rotating electrical machine.

A rotating electrical machine according to the present disclosure includes a housing and a rotor supported by the housing so as to be rotatable about a rotation axis. The rotating electric machine has a coolant reservoir that is located adjacent to an end surface of the rotor and that accumulates coolant. The coolant reservoir is formed by a first side surface defined by the rotor end surface, a second side surface defined by an inner wall surface of the casing facing the rotor end surface, and a peripheral surface defined by a peripheral wall extending in the circumferential direction around the rotation axis of the rotor between the rotor end surface and the inner wall surface of the casing. The peripheral wall includes a housing-side peripheral wall provided upright on the housing inner wall surface and extending in the circumferential direction around the rotation axis, and a rotor-side peripheral wall provided upright on the rotor end surface and extending over the entire circumference around the rotation axis. The rotating electric machine has a coolant flow passage extending in a direction along the rotation axis and penetrating the rotor. One end of the coolant flow channel is disposed so as to be open to the coolant reservoir.

The coolant flows from the coolant reservoir to the coolant flow passage, and the rotor can be cooled from inside.

The rotor-side circumferential wall may be located radially outward of the case-side circumferential wall, and may have an inward flange at a tip edge thereof, the inward flange extending radially inward and having a tip abutting an outer surface of the case-side circumferential wall. This can reduce the gap between the rotor-side peripheral wall and the housing-side peripheral wall, and facilitate the accumulation of the coolant.

The rotor may include a rotor core plate (rotor core plate) laminated in a direction along the rotation axis to form a rotor core, and end plates (end plates) positioned at both ends of the laminated rotor core plate, and the rotor core plate may be configured such that end plate cooling holes that become part of the coolant flow channels are formed in the end plate on the coolant reservoir side, and core plate cooling holes that become part of the coolant flow channels and are positioned at positions shifted radially outward from the end plate cooling holes are formed in the rotor core plate.

By radially offsetting the end plate cooling holes and the core plate cooling holes, portions inclined in the coolant flow channel can be produced. Further, the centrifugal force generated by the rotation of the rotor acts on the coolant in the inclined portion, thereby promoting the flow of the coolant in the coolant path.

Even when the coolant cannot be supplied to the interior of the rotor via the output shaft of the rotating electrical machine, the coolant can be supplied from the rotor end face to the interior of the rotor.

Drawings

Fig. 1 is a schematic diagram showing a cross section of a rotating electric machine according to the present embodiment.

Fig. 2 is a perspective view showing the rotor.

Fig. 3 is a view showing an end face of the rotor.

Fig. 4 is a perspective view showing an end cover as a part of the housing.

Fig. 5 is a view showing the periphery of the bearing holding portion of the end shield.

Fig. 6 is a schematic diagram showing the structure of the coolant reservoir.

Detailed Description

Hereinafter, embodiments of the present disclosure will be described with reference to the drawings. Fig. 1 is a sectional view schematically showing a main part structure of a rotating electric machine 10 according to the present embodiment. The rotating electric machine 10 includes: a rotor 12 supported so as to be rotatable about a rotation axis L, and a stator 14 disposed so as to surround the rotor 12. The rotor 12 and the stator 14 are housed in a case 16, the rotor 12 is rotatably supported by the case 16, and the stator 14 is fixed to the case 16. The rotating electrical machine 10 is disposed so that the rotation axis L is horizontal when installed or used. Hereinafter, a direction along the rotation axis L is referred to as an axial direction, a direction around the rotation axis L is referred to as a circumferential direction, and a direction perpendicular to the rotation axis L is referred to as a radial direction.

The stator 14 includes a stator core 18 having a cylindrical shape as a whole, and having a plurality of teeth arranged at intervals in the circumferential direction at the inner periphery of the cylinder, and a coil 20 wound around the teeth. The stator core 18 is formed by laminating a plurality of electromagnetic steel sheets formed into a predetermined shape in a direction along the rotation axis L. In fig. 1, the coil 20 exhibits only a portion protruding from an end face of the stator 14 in the axial direction, a so-called coil end 22. A predetermined alternating current is applied to the coil, thereby forming a rotating magnetic field in the space inside the cylinder of the stator 14.

The rotor 12 includes a rotor core 24 having a substantially cylindrical shape, and a rotor shaft 26 penetrating the rotor core 24 along a center line of the cylinder. The rotor core 24 is formed by laminating a plurality of electromagnetic steel sheets formed into a predetermined shape in a direction along the rotation axis L. The electromagnetic steel sheet forming the rotor core 24 is referred to as a rotor core plate. The rotor shaft 26 is supported by the housing 16 via a bearing such that the center line thereof coincides with the rotation axis L. The rotor core 24 is sandwiched by end plates 28, 30 from both ends in the axial direction. The end plate 28 is referred to as a first end plate 28 and the end plate 30 is referred to as a second end plate 30. The rotor 12 rotates around the rotation axis L by interacting with the rotating magnetic field formed by the stator 14.

The rotor core 24 and the rotor shaft 26 are coupled to each other and are rotatable integrally about the rotation axis L. The rotor shaft 26 is a hollow shaft, and a transmission shaft 32 penetrating the space is disposed in the inner space. The drive shaft 32 is also rotatably supported by the housing 16 via a bearing, and is coupled to the rotor shaft 26 at the right outer side of the range shown in fig. 1. At the left end of the drive shaft 32, a coupling 34 for coupling with another shaft or a driving object is provided.

A plurality of coolant flow passages 36 extending in the axial direction are arranged in the circumferential direction in the rotor 12. The coolant flow channel 36 is formed by connecting a hole (hereinafter, core plate cooling hole 38) opened in each rotor core plate forming the rotor core 24 to holes 40, 42 opened in the first and second end plates 28, 30. The holes 40 of the first end plate 28 are referred to as first end plate cooling holes 40 and the holes 42 of the second end plate 30 are referred to as second end plate cooling holes 42.

The housing 16 includes a housing main body 44 that surrounds the periphery of the stator 14, and an end cover 46 that covers an open end of the housing main body 44. The end shield 46 has a bearing holding portion 48 that holds a bearing that supports the rotor shaft 26 and the transmission shaft 32.

Fig. 2 is a perspective view showing the rotor 12, and fig. 3 is a view showing an end face of the rotor 12 on the end cover 46 side. The first end plate 28 is located at a position adjacent to the end of the rotor core 24 on the end cover 46 side. The first end plate 28 includes a circular plate-shaped base plate portion 50, the base plate portion 50 being centrally opened with a hole through which the rotor shaft 26 passes, and a rotor-side peripheral wall 52, the rotor-side peripheral wall 52 being a circular-ring-shaped peripheral wall that is provided upright on the base plate portion 50. The surface of the base plate 50 facing the end cover 46 is an end surface of the rotor 12, and the rotor-side peripheral wall 52 is a wall that is provided upright outside the end surface and extends around the rotation axis L so as to extend over the entire circumference. The first end plate cooling hole 40 is opened in the substrate portion 50 so as to be adjacent to the inside of the rotor-side peripheral wall 52.

Fig. 4 is a perspective view showing the inside of the housing of the end cover 46, and fig. 5 is a view of the bearing holding portion 48 of the end cover 46 as viewed in the direction along the rotation axis L. The housing inner wall surface 54 as a surface of the housing inner side of the end shield 46 includes the bearing holding portion 48. A housing-side peripheral wall 56 extending in the circumferential direction around the rotation axis L is provided upright on a surface of the bearing holding portion 48 facing the rotor 12. The case-side peripheral wall 56 has an arc shape, and is provided so as to surround the rotor shaft 26 below the rotor shaft 26 when the rotary electric machine 10 is installed. The case-side peripheral wall 56 is provided such that one end 56r on the rear side in the rotational direction a of the rotor 12 is higher than one end 56f on the front side. In the rotary electric machine 10, the case-side peripheral wall 56 has an arc shape with a center angle of 180 °, that is, a semicircular shape.

As can be seen from fig. 1, the rotor-side peripheral wall 52 and the housing-side peripheral wall 56 are disposed close to each other, and the gap therebetween is made narrow. The gap is narrowed to such an extent that the passage of oil for lubricating the movable portion and cooling the heat generating portion is suppressed. Hereinafter, the engine oil will be referred to as a coolant. As described above, by reducing the gap between the rotor-side peripheral wall 52 and the case-side peripheral wall 56 to suppress the flow of the coolant, the coolant reservoir 58 can be formed in the portion between the rotor 12 and the case 16, and the coolant reservoir 58 receives and accumulates the coolant that is sent to the upper portion in the case 16 and flows downward thereafter. The coolant flow channel 36 provided in the rotor 12 is disposed so as to be open to the coolant reservoir 58 at the end portion on the end cover 46 side.

Fig. 6 is an enlarged cross-sectional view showing a portion where an end surface of the rotor 12 faces an inner wall surface of the housing, in particular, a portion around the rotor-side peripheral wall 52 and the housing-side peripheral wall 56. The rotor-side peripheral wall 52 is located radially outward of the housing-side peripheral wall 56, and the distal ends of the rotor-side peripheral wall 52 and the housing-side peripheral wall 56 are adjacent to each other in the radial direction. An inward flange 60 extending radially inward is provided at the tip edge of the rotor-side peripheral wall 52 over the entire circumference. By improving the dimensional accuracy of the distal end of the inward flange 60 by machining or the like, the gap with the case-side peripheral wall 56 can be reduced, and the coolant can be efficiently stored.

The coolant reservoir 58 is formed by a first side surface and a second side surface defined by the end surface of the rotor 12 and the inner wall surface of the casing 16 facing each other, and a peripheral surface defined by the rotor-side peripheral wall 52 and the casing-side peripheral wall 56. The first side surface is defined by an end surface of the rotor 12, specifically, an inner portion of the rotor-side peripheral wall 52 of the surface of the base plate portion 50 of the first end plate 28 facing the housing 16 in the axial direction. The second side surface is defined by an arcuate portion of the housing inner wall surface 54 (see fig. 4) inside the housing side peripheral wall 56. In particular, in this embodiment, the second side is semi-circular. The circumferential surfaces are defined by an inner circumferential surface 56a of the case side circumferential wall 56, a distal end edge surface 56b, an outer circumferential surface 56c on the distal end side of the inward flange 60, an inner circumferential surface 52a of the rotor side circumferential wall 52, and an inner side surface 60a of the inward flange 60.

The first end plate cooling hole 40, which is a part of the coolant flow passage 36, is formed adjacent to the rotor-side peripheral wall 52 on the radially inner side of the rotor-side peripheral wall 52. The core plate cooling holes 38 and the second end plate cooling holes 42 that form the coolant flow passages 36 together with the first end plate cooling holes 40 are formed so as to be offset radially outward from the first end plate cooling holes 40 while maintaining the portions that overlap the first end plate cooling holes 40. Thereby, an inclination is formed at a portion where the first end plate cooling hole 40 adjoins the core plate cooling hole 38. When the rotor 12 rotates, the centrifugal force acting on the coolant at the inclined portion acts as a driving force that causes the coolant to fall along the inclination (to be moved outward in the radial direction). This driving force promotes the flow of the coolant from the coolant reservoir 58 through the rotor core 24 toward the end face of the rotor 12 on the opposite side.

In the rotary electric machine 10, the coolant stored in the lower portion of the casing 16 is sent to the upper portion by a pump (not shown), and is sprayed on the coil 20 that generates heat, particularly on the coil end 22, thereby cooling these components. In addition, the cooling liquid also lubricates the bearing. A part of the coolant that has passed through the coil end 22 is received by the coolant reservoir 58 and is stored therein. The coolant is raised by the rotor 12 or a structure that rotates together with the rotor 12, and a part of the raised coolant is also received by the coolant reservoir 58. The opening of each coolant flow passage 36 on the coolant reservoir 58 side intermittently sinks into the coolant reservoir 58 as the rotor 12 rotates. When the opening of the coolant flow channel 36 is open to the coolant reservoir 58, the coolant flows from the coolant reservoir 58 through the coolant flow channel 36 to the opposite end surface, and in the process, the rotor core 24 is cooled from the inside.

In the rotating electrical machine 10, the rotor-side peripheral wall 52 and a part of the housing-side peripheral wall 56 are configured to face each other in the radial direction, but the present invention is not limited to this, and the rotor-side peripheral wall and the housing-side peripheral wall may be arranged so that the leading edges thereof face each other. Instead of the inward flange 60 provided on the rotor-side peripheral wall 52, an outward flange may be provided on the housing-side peripheral wall 56.

In the case of adopting a coaxial structure in which the transmission shaft 32 is inserted into the hollow rotor shaft 26 as in the rotary electric machine 10, it is difficult to supply the coolant to the rotor core 24 via the rotor shaft 26. In the rotary electric machine 10, the coolant reservoir 58 is provided so as to face the end face of the rotor 12, and the coolant can be sent from this position to the inside of the rotor core 24. In addition, even when a solid shaft structure is employed in which no coolant flow channel is provided in the rotor shaft, the coolant can be fed from the end face of the rotor to the inside of the rotor core.

Description of the symbols

10 … rotating electrical machine; 12 … a rotor; 14 … a stator; 16 … a housing; 18 … stator core; 20 … coil; 22 … coil ends; 24 … rotor core; 26 … rotor shaft; 28 … a first end panel; 30 … second end panel; 32 … drive shaft; 34 … shaft coupling; 36 … coolant flow path; 38 … core plate cooling holes; 40 … first end plate cooling holes; 42 … second end plate cooling holes; 44 … a housing body; 46 … end shield; 48 … bearing holding portion; 50 … substrate portion; 52 … rotor-side peripheral wall; 54 … inner wall surface of the housing; 56 … housing side peripheral walls; 58 … coolant reservoir; 60 ….