KR20230038794A - rotating electric machine - Google Patents

Abstract

According to the embodiment, a rotating electric machine includes a rotor 16 having a shaft 30 and a rotor core 32, a stator core 24 disposed around the rotor core, and a stator coil 28. A stator 14 having a stator 14, an outer case 18 covering the rotor and the stator, and a first outer case provided at one end side of the rotor core in the axial direction and having a maximum diameter larger than the inner diameter of the stator core. A cooling fan FA, a second cooling fan FB provided on the other end side in the axial direction of the rotor core within the outer case and having a maximum diameter smaller than the inner diameter of the stator core, along the outer circumference of the stator core A ventilation duct 40 having a flow path extending in the axial direction and an exhaust port 44 open to the flow path CH is provided. The passage has a first end 40a communicating with the space inside the outer case from the side of the first cooling fan and a second end 40b communicating with the space inside the outer case from the side of the second cooling fan, and the exhaust port has the first end and the second end 40b. It is axially shifted to the second end side with respect to the middle of the second end.

Description

rotating electric machine

An embodiment of the present invention relates to a rotating electric machine.

BACKGROUND OF THE INVENTION Usually, a rotating electric machine includes a cylindrical stator and a cylindrical rotor rotatably supported inside the stator. The stator includes a stator core and stator windings attached to the stator core. Most of the stator and rotor are covered by an outer case or frame.

[0002] In recent years, for the purpose of quality improvement and reduction of maintenance load, a conversion from an open type to a completely closed type has been progressing also in a rotating electric machine for driving a vehicle. Unlike the open type, the completely closed type dissipates heat generated in the device through an outer shell such as a frame, so the temperature of the stator winding (coil) or the like tends to increase.

When the temperature of the stator winding rises, the deterioration of the insulating material covering the winding accelerates, shortening the life of the rotating electric machine. Maintenance related to the stator winding is an overhaul accompanying disassembly, and the work becomes cumbersome when the maintenance interval is shortened. In order to reduce the number of times of maintenance, it is necessary to enhance the cooling performance of the rotary electric machine.

In a rotary electric machine having rotating disks (fans) on both sides of a rotor core, the larger the diameter of the rotating disks, the higher the static pressure of the fan, and thus the higher the flow rate and the higher the flow rate of outside air. On the other hand, since a rotating electric machine is assembled by inserting a rotor into the inner diameter side of the stator, it is necessary to suppress the diameter of at least one of the rotating discs to be less than or equal to the diameter of the rotor. On the side where the diameter of the rotating disk is small, the flow rate of internal and external air decreases, and the thermal resistance increases. Therefore, it is difficult to cool the stator windings and the like on both sides of the rotor core in a balanced manner, resulting in a large maximum temperature rise.

Japanese Unexamined Patent Publication No. 2006-25521 Japanese Unexamined Patent Publication No. 2014-103762 Japanese Unexamined Patent Publication No. 2018-74727 Japanese Unexamined Patent Publication No. 2002-19965 Japanese Unexamined Patent Publication No. 11-41872

The present invention has been made in view of the above points, and its object is to provide a rotating electric machine with improved cooling properties.

According to an embodiment, a rotating electric machine includes a shaft rotatable around a central axis, a rotor having a cylindrical rotor core installed on the shaft, and a cylindrical rotor disposed around the rotor core with a gap therebetween. A stator having a stator core and a stator coil installed on the stator core, an outer case supporting the stator and the rotor and covering the rotor and the stator, and a shaft of the rotor core within the outer case. a first cooling fan provided rotatably around the central axis at one end side in the direction and having a maximum diameter larger than the inner diameter of the stator core; and the other end side in the axial direction of the rotor core within the outer case. a second cooling fan provided rotatably around the central axis and having a maximum diameter smaller than the inner diameter of the stator core; a first end communicating with the space within the outer case from the side of the first cooling fan; 2 a flow path extending in the axial direction along an outer circumference of the stator core and having a second end communicating with the space within the outer case from the side of the cooling fan; A ventilation duct having an exhaust port is provided, and the exhaust port is positioned offset from the axial direction on the side of the second end with respect to the middle of the first end and the second end.

1 is a longitudinal sectional view showing a part of a rotary electric machine according to a first embodiment.
Fig. 2 is a sectional view of the rotary electric machine along line AA in Fig. 1;
Fig. 3 is a perspective view showing a first fan of the rotary electric machine.
Fig. 4 is a longitudinal sectional view showing a part of a rotary electric machine according to a second embodiment.
Fig. 5 is a longitudinal sectional view showing a part of a rotary electric machine according to a third embodiment.
Fig. 6 is a longitudinal sectional view showing a part of a rotary electric machine according to a fourth embodiment.
Fig. 7 is a longitudinal sectional view showing a part of a rotary electric machine according to a fifth embodiment.

EMBODIMENT OF THE INVENTION Below, embodiment of this invention is described, referring drawings. In addition, the same code|symbol shall be attached|subjected to the common structure through embodiment, and overlapping description is abbreviate|omitted. In addition, each drawing is a schematic diagram for facilitating the embodiment and its understanding, and although there are places where the shape, dimensions, ratio, etc. differ from the actual device, these can be appropriately designed and changed in consideration of the following description and well-known techniques. .

(First Embodiment)

Fig. 1 is a longitudinal cross-sectional view showing a portion divided in half along the central axis of the rotary electric machine according to the first embodiment, and Fig. 2 is a cross-sectional view of the first fan side of the rotary electric machine taken along the line A-A in Fig. 1. .

As shown in Fig. 1, the rotary electric machine 10 is configured as a so-called completely enclosed rotary electric machine. The rotating electric machine 10 includes an outer case 18 in which the inside is sealed, a cylindrical stator (stator) 14 disposed inside the outer case 18, and a rotor provided rotatably inside the stator ( rotor) (16).

The outer case (shell) 18 includes a substantially cylindrical support frame 12, an annular first end plate 34a that closes one end of the support frame 12 in the axial direction, and the support frame 12. An annular second end plate 34b that closes the other end in the axial direction of and a disc connected to the support frame 12 and the first end plate 34a and opposing the first end plate 34a with a gap therebetween. It is connected to the first bracket 19 of the top, the support frame 12 and the second end plate 34b and is provided with a disk-shaped second bracket 20 facing the second end plate 34b with a gap therebetween. .

In the center of the first bracket 19, a first bearing housing 22a containing the bearing B1 is integrally provided. To the center of the second bracket 20, a second bearing housing 22b containing the bearing B2 is bolted. The bearing B1 and the bearing B2 are aligned and arranged along the central axis C1 of the rotary electric machine 10 . The first bracket 19 has a plurality of first ventilation holes 23a formed through the first bearing housing 22a. The first ventilation hole 23a is located around the bearing B1 and communicates with the inner space of the outer case 18 . Similarly, the second bracket 20 has a plurality of second ventilation holes 23b formed through the second bearing housing 22b. The second ventilation hole 23b is located around the bearing B2 and communicates with the inner space of the outer case 18 .

The stator 14 has an annular or cylindrical stator core 24 and a stator coil 28 wound around the stator core 24 . The stator iron core 24 is supported by the support frame 12 in a state where its outer circumferential surface is fitted to the inner circumferential surface of the support frame 12, and is disposed coaxially with the central axis C1. A pair of annular iron core pressing members 26 are fixed to both end faces of the stator core 24 in the axial direction. The stator core 24 is formed by laminating a plurality of annular metal plates made of a magnetic material, for example, a silicon steel plate. A plurality of slots each extending in the axial direction are formed on the inner periphery of the stator iron core 24. The stator coil 28 is installed in the stator core 24 in a state of being embedded in these slots. The coil ends 28e of the stator coil 28 protrude from both end faces of the stator core 24 in the axial direction. Between the coil end 28e and the end face of the stator iron core 24, a gap through which the bet can flow is provided.

The rotor 16 includes a rotating shaft 30, a rotor core 32, a plurality of rotor bars 52 embedded in the rotor core 32, and both ends of the rotor bars 52 connected. Equipped with a pair of end rings. The rotating shaft 30 is disposed within the outer case 18 coaxially with the central axis C1, and is rotatably supported at one end and the other end in the axial direction by bearings B1 and B2, respectively. At least one end of the rotating shaft 30 extends out of the machine through a bearing.

The rotor iron core 32 is formed by laminating a plurality of annular metal plates made of a magnetic material, for example, a silicon steel plate, and is formed in a substantially cylindrical shape. The rotor core 32 is installed substantially at the center of the rotating shaft 30 in the axial direction, and is disposed inside the stator core 24 coaxially with the central axis C1. The outer circumferential surface of the rotor core 32 faces the inner circumferential surface of the stator core 24 with a gap G therebetween. The axial length of the rotor core 32 is formed substantially equal to the axial length of the stator core 24, and the rotor core 32 opposes the stator core 24 over the entire length.

A plurality of slots (grooves) 50 each extending in the axial direction are formed on the outer periphery of the rotor iron core 32, and are arranged at regular intervals in the circumferential direction. Each slot 50 extends through the rotor core 32 in the axial direction and is open to both end faces of the rotor core 32 . The rotor bar 52 is inserted into each slot 50 and extends in the axial direction of the rotor core 32 .

The rotary electric machine 10 includes a cooling mechanism for cooling the inside of the outer case 18 including the stator coil 28 . That is, the rotating electric machine 10 includes a first cooling fan FA installed on the rotating shaft 30 and located between the first bracket 19 and the rotor core 32, and the rotating shaft 30 and air generated by the second cooling fan FB, which is installed between the second bracket 20 and the rotor core 32, and the first cooling fan FA and the second cooling fan FB. A plurality of ventilation ducts 40 are provided to flow the flow along the outer circumferential surface of the outer case 18.

3 is a perspective view showing an example of the first cooling fan.

As shown in FIG. 1 and FIG. 3, the 1st cooling fan FA is comprised as a centrifugal fan, and generates wind in the radial direction by rotation. The 1st cooling fan FA is equipped with the fan main body 70a of a trumpet shape or fan shape. The fan main body 70a is fixed to the rotating shaft 30, and protrudes from the side of the rotor core 32 toward the first bracket 19 and extends toward the outer circumferential side in the radial direction. The first cooling fan FA is provided between an annular inner shroud 70b disposed opposite to the inner surface of the iron core side of the fan body 70a with a gap between the fan body 70a and the inner shroud 70b. A plurality of inner blades 80, an annular outer shroud 70c disposed opposite to each other with a gap on the outer circumferential surface of the fan body 70a on the side of the first bracket 19, the fan body 70a and the outer shroud ( It has a plurality of outer blades 81 provided between 70c).

The inner blades 80 are provided with Ni sheets and are arranged at equal intervals from each other in the circumferential direction centered on the central axis line C1. The inner blade 80 extends radially or radially with respect to the central axis C1. No number of outer blades 81 are provided, and are arranged at equal intervals from each other in the circumferential direction centered on the central axis line C1. The outer blade 81 extends radially or radially with respect to the central axis C1. The number of inner blades 80 (Ni) is set higher than the number of outer blades 81 (No) (Ni>No).

As shown in FIGS. 1 and 2 , the protruding end portion of the fan main body 70a on the side of the first bracket 19 is aligned with the first end plate 34a. That is, the extended protruding end of the fan body 70a is arranged in the inner hole of the first end plate 34a and faces the inner circumferential surface of the first end plate 34a with a slight gap therebetween. The outer diameter Dd1 of the extended protruding end centered on the central axis C1 is the maximum diameter of the first cooling fan FA, and is larger than the inner diameter Rd of the stator core 24 (Dd1 > Rd). ).

The outer diameter Dd2 centered on the central axis C1 of the inner blade 80 located on the iron core side with respect to the fan body 70a is the outer diameter with respect to the fan body 70a, that is, the first bracket 19 It is set larger than the outer diameter Dd3 centered on the central axis C1 of the outer blade 81 located on the side. The diameter of each part of the 1st cooling fan FA is set in the relationship of Dd1>Dd2>Dd3>Rd.

Between the outer circumferential surface of the fan body 70a and the outer circumferential end of the inner shroud 70b, an inner exhaust port 82a of the first cooling fan is defined. The inner exhaust port 82a is opened outward in the radial direction. The inside exhaust port 82a is located near the end of the coil end 28e, and it is preferable to set the wind from the first cooling fan FA to a position where it is difficult to collide with the coil end 28e. Between the outer peripheral surface of the fan body 70a and the inner peripheral end of the inner shroud 70b, the inner intake port 84a of the first cooling fan FA is defined. The inner intake port 84a is disposed adjacent to the rotor core 32.

Between the outer peripheral surface of the fan body 70a and the outer peripheral end of the outer shroud 70c, an outer exhaust port 82b of the first cooling fan is defined. The outside exhaust port 82b is open toward the outside in the radial direction. Between the outer peripheral surface of the fan body 70a and the inner peripheral end of the outer shroud 70c, the outer intake port 84b of the first cooling fan FA is defined. The outside intake port 84b is located near the first ventilation hole 23a of the first bracket 19 .

The region on the outer peripheral side of the first bracket 19 faces the first end plate 34a at a distance. An annular first diffusion ventilation passage (first space) AF1 is defined between the first end plate 34a and the first bracket 19. The first diffusion passage AF1 communicates with the space SA1 between the fan body 70a and the first bracket 19, and the space SA1 has a plurality of first ventilation holes 23a. It communicates outside the device through The outer shroud 70c and outer blades 81 of the first cooling fan FA are located in the space SA1 and face the first diffusion ventilation passage AF1.

The 2nd cooling fan FB has substantially the same structure as the 1st cooling fan FA, and is comprised as a centrifugal fan. As shown in FIG. 1, the 2nd cooling fan FB is provided with the fan main body 72a of a trumpet shape or fan shape. The fan main body 72a is fixed to the rotating shaft 30, and protrudes from the side of the rotor core 32 toward the second bracket 20 and extends toward the outer circumferential side in the radial direction. The second cooling fan FB is provided between an annular inner shroud 72b disposed opposite to each other with a gap on the inner surface of the iron core side of the fan main body 72a, and between the fan main body 72a and the inner shroud 72b. A plurality of inner blades 86, an annular outer shroud 72c arranged opposite to each other with a gap on the outer circumferential surface of the fan body 72a on the side of the second bracket 20, the fan body 72a and the outer shroud ( It has a plurality of outer blades 88 provided between 72c) integrally.

The inner blades 86 are provided with Ni sheets and are arranged at equal intervals from each other in the circumferential direction centered on the central axis line C1. The inner blade 86 extends radially or radially with respect to the central axis C1. No number of outer blades 88 are provided, and they are arranged at equal intervals from each other in the circumferential direction centered on the central axis line C1. The outer blade 88 extends radially or radially with respect to the central axis C1. The number of inner blades 86 (Ni) is set higher than the number of outer blades 88 (No) (Ni>No).

The extended protruding end of the fan body 72a on the side of the second bracket 20 is positioned parallel to the second end plate 34b. That is, the extended protruding end of the fan body 72a is arranged in the inner hole of the second end plate 34b and faces the inner circumferential surface of the second end plate 34b with a slight gap therebetween. The outer diameter Dd4 of the extended protruding end centered on the central axis C1 is the maximum diameter of the second cooling fan FB and is smaller than the inner diameter Rd of the stator core 24 (Dd4 < Rd ).

The outer diameter Dd5 centered on the central axis C1 of the inner blade 86 located on the iron core side with respect to the fan body 72a is the outer diameter with respect to the fan body 72a, that is, the second bracket 20 It is set larger than the outer diameter Dd6 centered on the central axis C1 of the outer blade 88 located on the side. The diameter of each part of the first cooling fan FA is set in the relationship of Rd>Dd4>Dd5>Dd6.

Between the outer peripheral surface of the fan body 72a and the outer peripheral end of the inner shroud 72b, an inner exhaust port 85a of the second cooling fan is defined. The inner exhaust port 85a is opened outward in the radial direction. The inside exhaust port 85a is located in the vicinity of the end of the coil end 28e, and it is preferable to set the wind from the second cooling fan FB to a position where it is difficult to collide with the coil end 28e. Between the outer peripheral surface of the fan body 72a and the inner peripheral end of the inner shroud 72b, an inner intake port 87a of the second cooling fan FB is defined. The inner intake port 87a is disposed adjacent to the rotor core 32.

Between the outer peripheral surface of the fan body 72a and the outer peripheral end of the outer shroud 72c, the outer exhaust port 85b of the second cooling fan FB is defined. The outside exhaust port 85b is open toward the outside in the radial direction. Between the outer peripheral surface of the fan main body 72a and the inner peripheral end of the outer shroud 72c, the outer intake port 87b of the 2nd cooling fan FB is defined. The outside intake port 87b is located in the vicinity of the second ventilation hole 23b of the second bracket 20 .

The area on the outer peripheral side of the second bracket 20 faces the second end plate 34b at a distance. Between the second end plate 34b and the second bracket 20, an annular second diffusion ventilation passage (second space) AF2 is defined. The second diffusion ventilation path AF2 communicates with the space SA2 between the fan main body 72a and the second bracket 20, and the space SA2 includes a plurality of second ventilation holes 23b. It communicates outside the device through The outer shroud 72c and the outer blade 88 of the second cooling fan FB are located in the space SA2 and face the second diffusion ventilation passage AF2.

On the other hand, the ventilation duct 40 is provided on the outer circumferential surface of the support frame 12 and extends from the first bracket 19 to the second bracket 20 along the axial direction of the support frame 12 . The ventilation duct 40 forms a flow path CH through which cooling air flows. The flow path CH has a first end portion 40a communicating with the first diffusion ventilation passage AF1 and a second end portion 40b communicating with the second diffusion ventilation passage AF2, and is provided with a support frame 12 and It extends axially over the entire length of the stator 14 .

The ventilation duct 40 has an exhaust port 44 formed substantially in the middle of the axial direction and communicating with the flow path CH. When the center (center) in the axial direction of the stator 14, the support frame 12, and the flow channel CH is the central axis CC, the exhaust port 44 has the center HC in the axial direction of the central axis ( CC) is provided at a position shifted in the axial direction. In this embodiment, the exhaust port 44 is axially shifted by the shift amount D1 on the side of the small-diameter second cooling fan FB with respect to the central axis CC.

Accordingly, the length L1 of the passage CH from the first end 40a to the center HC is longer than the length L2 from the second end 40b to the center HC (L1 > L2 ). That is, the flow path CH on the side of the second cooling fan FB with a small diameter is formed shorter than the flow path CH on the side of the first cooling fan FA with a large diameter.

Further, the width of the exhaust port 44 in the axial direction and the amount of displacement D1 are arbitrarily set according to the flow rate of the cooling air flowing through the flow path CH.

A plurality of ventilation ducts 40 configured as above are provided, for example, four. As shown in FIG. 2 , four ventilation ducts 40 are provided on the outer periphery of the support frame 12 at regular intervals in the circumferential direction around the central axis C1. In addition, it is assumed that the diameter of the flow path CH formed by the ventilation duct 40 is constant over the entire length of the ventilation duct 40, and that the four ventilation ducts 40 are formed with the same diameter. .

A cooling action of the rotary electric machine 10 configured as described above will be described.

As shown in FIG. 1 , during operation of the rotary electric machine 10 , the first cooling fan FA and the second cooling fan FB rotate integrally with the rotor 16 . When the first cooling fan FA rotates, air flow is generated by the outer blades 81 . Thereby, outside air is sucked into the space SA1 through the first ventilation hole 23a. The introduced outside air passes between the outer blades 81 from the outer intake port 84b of the first cooling fan and flows out from the outer exhaust port 82b in a radial direction. The discharged outside air flows into the passage CH of the ventilation duct 40 through the first diffusion passage AF1, flows along the passage CH, and then is exhausted out of the device through the exhaust port 44. By contacting the outside air in this way, the first cooling fan FA, the first end plate 34a, the support frame 12, and the stator iron core 24 are cooled by the outside air.

At the same time, when the first cooling fan FA rotates, an air current is generated in the machine from the inner blades 80. The airflow passes between the inner blades 80 from the inner intake port 84a of the first cooling fan FA and flows out from the inner exhaust port 82a in the radial direction. The discharged iron returns to the inner intake port 84a of the first cooling fan FA through the periphery of the coil end 28e and through the gap between the coil end 28e and the stator core 24. Thus, by circulating the coil around the coil end 28e, the coil end 28e is cooled. At this time, since the circulating inside air is cooled by the outside air through the first end plate 34a and the support frame 12 and the temperature is lowered, it contributes to the cooling of the coil end 28e.

On the other hand, when the second cooling fan FB rotates, an airflow is generated by the outer blades 88. Thereby, outside air is sucked into the space SA2 through the second ventilation hole 23b. The introduced outside air passes between the outer blades 88 from the outer intake port 87b of the second cooling fan FB and flows out from the outer exhaust port 85b in a radial direction. The discharged outside air flows into the passage CH of the ventilation duct 40 through the second diffusion ventilation passage AF2, flows along the passage CH, and then is exhausted out of the device through the exhaust port 44. Thus, the 2nd cooling fan FB, the 2nd end plate 34b, the support frame 12, and the stator iron core 24 are cooled by outside air by contacting with outside air.

At the same time, when the second cooling fan FB rotates, an air current is generated within the machine from the inner blades 86. The air flow passes between the inner blades 86 from the inner intake port 87a of the second cooling fan FB and flows out from the inner exhaust port 85a in the radial direction. The discharged iron returns to the inner intake port 87a of the second cooling fan FB through the periphery of the coil end 28e and through the gap between the coil end 28e and the stator core 24. Thus, by circulating the coil around the coil end 28e, the coil end 28e is cooled. At this time, since the circulating inner air is cooled by the outside air through the second end plate 34b and the support frame 12 and the temperature is lowered, it contributes to the cooling of the coil end 28e.

As described above, the stator 14 and the coil end 28e can be efficiently cooled by the air flow formed by the first cooling fan FA and the second cooling fan FB. When assembling the rotating electric machine 10, at least one cooling fan needs to have an outer diameter smaller than the inner diameter of the stator core 24 so that it can be inserted through the inner hole of the stator core 24. Therefore, in this embodiment, the maximum diameter Dd4 of the second cooling fan FB is made smaller than the inner diameter Rd of the stator core 24, and the maximum diameter Dd1 of the first cooling fan FA is It is formed larger than the inner diameter Rd of the stator iron core 24. In such a rotating electric machine 10, the static pressure Px generated by rotation of the first cooling fan FA having a large diameter is the static pressure generated by rotation of the second cooling fan FB having a small diameter ( It is larger than Py). Therefore, the outside air flow rate flowing into the flow path CH of each ventilation duct 40 can be larger on the first cooling fan FA side than on the second cooling fan FB side.

Here, according to the present embodiment, the exhaust port 44 of the ventilation duct 40 is provided shifted by D1 to the second cooling fan FB side with respect to the central axis CC, and the first end of the flow path CH ( The length L1 from 40a) to the center HC of the exhaust port 44 is longer than the length L2 from the second end 40b to the center HC (L1 > L2). Therefore, although the static pressure Py on the side of the second cooling fan FB is smaller than the static pressure Px on the side of the first cooling fan FA, the outside air flow rate Qy on the side of the second cooling fan FB It is possible to increase to equal to the outside air flow rate (Qx) on the first cooling fan (FA) side. That is, the thermal resistance on the side of the small-diameter second cooling fan FB can be made low. Therefore, it is possible to reduce unbalance of cooling performance in the free air cooling area on both sides in the axial direction of the stator iron core 24 where the first cooling fan FA and the second cooling fan FB having different diameters are disposed. do. As a result, the cooling performance of the coil end 28e located on the side of the small-diameter second cooling fan FB is relatively improved, and the temperature of the stator coil 28 can be reduced efficiently.

From the above, according to the first embodiment, the stator and the rotor are cooled in a balanced manner on both sides in the axial direction, thereby obtaining a rotating electric machine with improved cooling properties.

In addition, in 1st Embodiment, the shape and size of the exhaust port of a ventilation duct are variously changeable without being limited to embodiment. The exhaust port is not limited to one, and may be provided in multiple numbers.

Next, a rotating electric machine according to another embodiment of the present invention will be described. In another embodiment described below, the same reference numerals as in the first embodiment are given to the same parts and components as those of the first embodiment described above, and the explanations thereof are omitted or simplified, and the parts different from those of the first embodiment are omitted. will be explained based on

(Second Embodiment)

Fig. 4 is a longitudinal sectional view showing a part of the rotary electric machine according to the second embodiment.

As shown, according to the second embodiment, a partition plate 46 is disposed in the passage CH of the ventilation duct 40 . The partition plate 46 is erected almost vertically on the 18 circumferential surfaces of the frame, and is disposed facing the center HC of the exhaust port 44 in the axial direction. The partition plate 46 divides the flow path CH into left and right portions at approximately the center in the axial direction. That is, by the partition plate 46, the flow path CH is a first flow path extending from the first end portion 40a to the exhaust port 44, and a second flow path extending from the second end portion 40b to the exhaust port 44. They are partitioned at 2 euros.

By providing the partition plate 46, the cooling air flowing through the flow path CH from the first end portion 40a of the ventilation duct 40 toward the exhaust port 44 comes into contact with the partition plate 46 and is discharged from the exhaust port 44. exhausted Cooling air flowing through the passage CH from the second end portion 40b toward the exhaust port 44 hits the partition plate 46 and is exhausted from the exhaust port 44 . That is, air streams flowing from both ends of the ventilation duct 40 toward the exhaust port 44 are exhausted from the exhaust port 44 to the outside of the device without colliding with each other within the flow path CH.

When air streams collide with each other, an unstable flow state occurs and the flow rate of both flow passages CH fluctuates. It is exhausted out of the device from the exhaust port 44. Therefore, it is possible to secure a predetermined flow rate of outside air flowing through the passage CH of the ventilation duct. This makes it possible to reduce unbalance in cooling performance in the free air cooling area on both sides in the axial direction of the stator core 24 where the first cooling fan FA and the second cooling fan FB having different diameters are disposed. will do

Further, in the second embodiment, the exhaust port 44 of the ventilation duct 40 may be provided such that the center HC coincides with the central axis CC of the stator 14 in the axial direction, or the center (HC) may be provided so as to be displaced from the central axis CC in the axial direction.

(Third Embodiment)

Fig. 5 is a longitudinal sectional view showing a part of a rotary electric machine according to a third embodiment.

As illustrated, according to the third embodiment, a plurality of fins 90a, 90b, and 90c are provided on the inner circumferential surface of the support frame 12 on the side of the second cooling fan FB having a small diameter. The pins 90a, 90b, and 90c are, for example, annular pins, are arranged coaxially with the central axis C1, and protrude from the inner circumferential surface of the support frame 12 toward the central axis C1. The fins 90a, 90b, and 90c are provided at intervals in the axial direction and oppose the inner blade 86 and the inner shroud 72b of the second cooling fan at intervals.

When assembling the rotating electric machine 10, since the stator core 24 is press-fitted into the support frame 12 from one end side of the support frame 12, on either side of the stator core 24 on the inner peripheral surface of the frame. Pins such as toroidal pins and straight pins cannot be placed outside. On the other hand, the agitation flow Qiy of the second cooling fan FB with a small diameter is smaller than the agitation flow Qix of the first cooling fan FA with a large diameter. However, as in the present embodiment, by providing the fins 90a, 90b, 90c in the support frame 12 on the side of the second cooling fan FB, the area within the device where the second cooling fan FB is installed is The heat resistance of the inner core can be lowered, and the unbalance of the cooling performance of the inner core area on both sides of the iron core on which the rotating disks of different diameters are disposed can be further reduced.

As a result, an imbalance of cooling performance can be achieved in the cooling area inside the machine (inside) on both sides in the axial direction of the stator iron core 24 where the first cooling fan FA and the second cooling fan FB having different diameters are disposed. reduction is possible.

The third embodiment can be combined with any of the first and second embodiments described above.

(Fourth Embodiment)

Fig. 6 is a longitudinal sectional view showing a part of a rotary electric machine according to a fourth embodiment.

As shown, according to the fourth embodiment, the inner shroud 72b of the second cooling fan FB having at least a small diameter has an annular flange portion 72d extending outward in the radial direction from the end of the intake side. ) as a whole. The flange portion 72d is provided coaxially with the central axis C1, and the outer diameter of the flange portion 72d is formed to have a diameter substantially equal to the inner diameter Rd of the stator core 24.

By adding such a flange portion 72d, it is possible to reduce the short-circuit airflow flowing out from the inner exhaust port 85a of the second cooling fan, short-circuiting the vicinity of the inner shroud 72b, and flowing into the inner intake port 87a. It becomes possible to sufficiently secure the flow rate of circulating air passing through the coil end 28e and prevent an increase in thermal resistance. As a result, an imbalance of cooling performance can be achieved in the cooling area inside the machine (inside) on both sides in the axial direction of the stator iron core 24 where the first cooling fan FA and the second cooling fan FB having different diameters are disposed. reduction is possible.

Moreover, it is good also as a structure in which the flange part was added also to the inner side shroud of the 1st cooling fan FA.

(Fifth Embodiment)

Fig. 7 is a longitudinal sectional view showing a part of a rotary electric machine according to a fifth embodiment.

As shown, according to the fifth embodiment, the inner shroud 72b of the small-diameter second cooling fan FB, in addition to the flange portion 72d, extends from the outer periphery of the flange portion 72d to the rotor iron core. It integrally has a cylindrical extension part 72e extending and protruding in the axial direction toward (32). The extension portion 72e is provided coaxially with the central axis C1, and the outer diameter of the extension portion 72e is formed to have a diameter substantially equal to the inner diameter Rd of the stator iron core 24.

By providing the extension portion 72e, the short-circuit air flow can be further reduced, and the flow rate of circulating air passing through the coil end 28e can be sufficiently secured to reduce thermal resistance. As a result, an imbalance of cooling performance can be achieved in the cooling area inside the machine (inside) on both sides in the axial direction of the stator iron core 24 where the first cooling fan FA and the second cooling fan FB having different diameters are disposed. It becomes possible to make it smaller.

The fifth embodiment can be combined with any of the first embodiment, the second embodiment, and the third embodiment described above.

Although several embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. Such a novel embodiment can be implemented in various other forms, and various omissions, substitutions, and changes can be made within a range not departing from the gist of the invention. While being included in the scope and gist of the invention, these embodiments and variations thereof are included in the scope of the invention described in the claims and their equivalents.

Claims (7)

A rotor having a shaft rotatable around a central axis and a cylindrical rotor core installed on the shaft;
a stator having a cylindrical stator core disposed around the rotor core with a gap therebetween, and a stator coil installed on the stator core;
an outer case supporting the stator and the rotor and covering the rotor and the stator;
a first cooling fan provided to be rotatable around the central axis at one end side of the rotor core in the axial direction within the outer case and having a maximum diameter larger than the inner diameter of the stator core;
a second cooling fan provided rotatably around the central axis at the other end side of the rotor core in the axial direction within the outer case and having a maximum diameter smaller than the inner diameter of the stator core;
having a first end communicating with the space within the outer case from the first cooling fan side and a second end communicating with the space within the outer case from the second cooling fan side, and extending in the axial direction along the outer circumference of the stator core. a ventilation duct having a flow path and an exhaust port open to the flow path between the first end and the second end, the exhaust port being at a side of the second end with respect to a middle of the first end and the second end; A rotating electric machine positioned displaced in the axial direction. According to claim 1,
A partition plate is provided in the flow path to face the exhaust port, and the flow path includes a first flow path extending from the first end to the exhaust port by the partition plate, and a second flow path extending from the second end to the exhaust port. A rotating electrical appliance, partitioned by 2 euros. According to claim 1,
A rotary electric machine comprising a plurality of fins provided on an inner surface side of the outer case and facing the second cooling fan at intervals. According to claim 1,
The stator coil has coil ends extending and protruding from one end in the axial direction and the other end in the axial direction of the stator core,
The first cooling fan generates an airflow that circulates around the coil end in a space between a fan body installed on the shaft, the fan body, and the stator core, the rotor core, and the outer case. It has a plurality of inner blades and an annular inner shroud fixed to the extended protruding ends of the inner blades,
The second cooling fan includes a fan body installed on the shaft and a plurality of sheets provided on the fan body and generating an air flow circulating around the coil end in a space between the stator core and the outer case. A rotating electric machine having an inner blade and an annular inner shroud fixed to an extended projecting end of the inner blade. According to claim 4,
The inner shroud of the second cooling fan has an annular flange portion extending outward in a radial direction from an end portion on the rotor core side, and the flange portion has an outer diameter substantially equal to an inner diameter of the stator iron core. rotating electric machine. According to claim 5,
wherein the inner shroud of the second cooling fan further includes an annular extension extending in the axial direction from an outer periphery of the flange portion to a vicinity of the rotor iron core. According to claim 1,
The outer case includes a cylindrical support frame supporting the stator iron core, a first end plate facing one end in the axial direction of the support frame, and a second end plate facing the other end in the axial direction of the support frame. An end plate, a first bracket disposed opposite to the first end plate with a gap therebetween, and a second bracket disposed opposite to the second end plate with a gap therebetween,
The first end of the flow path communicates with a first space between the first end plate and the first bracket, and the second end of the flow path is between the second end plate and the second bracket. communicates with the second space of
The first cooling fan is provided on a fan body provided on the shaft between the first bracket and the rotor core, and is provided on the fan body, passes through the first space, and flows into the flow path from the first end portion. Equipped with a plurality of outer blades that form an air flow,
The second cooling fan includes a fan body provided on the shaft between the second bracket and the rotor core, and air provided on the fan body and introduced into the flow path from the second end portion through the second space. A rotating electric machine equipped with a plurality of outer blades forming a flow.

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