JP7317270B2 - Rotating electric machine - Google Patents

Description

The present application relates to a rotating electric machine.

Conventionally, a rotating electric machine is connected to a rotating shaft provided at the center of rotation, and a mechanical transmission that slows down the rotation of the rotating electric machine has been used for applications that require low-speed drive. When a mechanical transmission is used, mechanical wear and the like occur in the transmission, so periodic maintenance is required. A rotary electric machine capable of changing the rotation speed of a rotor in a non-contact manner without using a mechanical transmission is disclosed as a magnetic wave gear device or a magnetic geared generator. A magnetic wave gear device comprises a stator having permanent magnets, a first rotor rotating at a low speed and having magnetic pole pieces, and a first rotor having magnetic pole pieces, which rotates at a high speed according to a gear ratio, from the outer peripheral side around a rotating shaft, A second rotor having permanent magnets is provided. The stator has stator coils capable of outputting generated power or controlling generated torque. By using this rotating electric machine, the rotation speed of the rotor can be varied without contact, so maintenance due to mechanical wear is not required, and the burden of maintenance can be reduced. In addition, if this rotating electric machine is used as a generator, it is possible to change speed and generate power with one rotating electric machine without a mechanical transmission, so that the power generation system can be downsized and space can be saved.

On the other hand, the allowable temperature of the rotating electrical machine is determined for each part of the rotating electrical machine. For example, the stator coil depends on the heat resistance temperature of the insulation coating, the permanent magnets of the stator and the second rotor depend on the demagnetizing temperature of the magnets, and the first rotor is interposed around the magnetic pole piece. The heat resistance temperature of the insulating material determines the appropriate allowable temperature for each part. When the temperature of each part of the rotating electric machine exceeds the allowable temperature, the risk of performance deterioration, life shortening, or malfunction of each part increases. Therefore, proper cooling of each part is extremely important. As a cooling technology for rotating electric machines, a cooling air flow A that blows into the ventilation path on the outer peripheral surface side of the casing and a cooling air flow B that blows into the ventilation path inside the machine are directed in opposite directions by using the outer skin cooling method. A technique for countercurrently blowing air is disclosed (see Patent Document 1, for example).

JP 2014-33584 A

In the rotary electric machine disclosed in Patent Document 1, the cooling air flow A and the cooling air flow B are blown in opposite directions, so that high cooling performance and relaxation of the internal temperature distribution can be achieved. However, there is a problem that it is not possible to suppress the variation in the temperature distribution that occurs in the first rotor and the second rotor of the magnetic wave gear device, and the temperature rise during operation. rice field. Moreover, since the temperature rise during operation is not suppressed, there is a problem that the output of the rotary electric machine cannot be increased.

SUMMARY OF THE INVENTION Accordingly, an object of the present application is to obtain a rotating electrical machine with increased output by suppressing an increase in variation in temperature distribution and an increase in temperature occurring in the first rotor and the second rotor.

A rotary electric machine disclosed in the present application includes a rotating shaft, a stator core having a plurality of stator slots that open radially inward in a circumferential direction, and a fixing member disposed on the bottom side of each of the plurality of stator slots. a child coil, a stator magnet arranged on the opening side of each of the plurality of stator slots so as to have the same magnetic pole direction in the radial direction, and provided between the stator coil and the stator magnet, A stator having a stator magnet cooling channel extending axially therethrough, a cylindrical first body portion, and a plurality of magnetic pole pieces provided on the first body portion at intervals in the circumferential direction. a first rotor that is provided coaxially with the stator so as to face the stator magnet and rotates integrally with the rotating shaft; a cylindrical second main body; and an outer peripheral portion of the second main body and a plurality of permanent magnets arranged at intervals in the circumferential direction, and provided coaxially with the first rotor facing the radially inner wall surface of the first main body a rotor, a peripheral wall surrounding the stator from the outside in the radial direction, a first inner wall connected to the peripheral wall and covering one axial side of the stator, the first rotor, and the second rotor, the a second inner wall connected to the peripheral wall and covering the other axial side of the stator, the first rotor, and the second rotor; a second inner wall connected to the peripheral wall and spaced apart in the axial direction of the first inner wall a housing having a first outer wall covering one side and a second outer wall connected to the peripheral wall and covering the other side of the second inner wall in the axial direction with a space therebetween; A fan for sending gas, and a heat exchanger disposed inside the housing through which the cooling gas passes, wherein the first main body extends in an axial direction between the second rotor and the first inner wall. extends radially inward from one end in the axial direction between the first end plate fixed to the rotating shaft and between the second rotor and the second inner wall in the axial direction and a second end plate extending radially inward from the other end in the axial direction and fixed to the rotating shaft; the second end plate has a second through hole axially penetrating in a radially outer portion thereof, and between the first main body portion and the second rotor, A first cooling channel communicating with the first through hole and the second through hole is formed, a second cooling channel is formed between the first body portion and the stator, and the first inner wall is a first inner wall inner through-hole that communicates with the first cooling channel and penetrates in the axial direction, and a first inner wall inner through-hole that communicates with the second cooling channel and the stator magnet cooling channel, a first inner wall outer through-hole axially penetrating at a radial position radially outer than the second inner wall inner side axially penetrating through the a through hole, and a second inner wall outer through hole that communicates with the second cooling flow path and the stator magnet cooling flow path and penetrates in the axial direction at a radial position radially outer than the second inner wall inner through hole wherein the fan is disposed between the first inner wall and the first outer wall and between the second inner wall and the second outer wall, or both; and the heat exchanger is disposed between the first disposed between one inner wall and the first outer wall and between the second inner wall and the second outer wall, or between the first cooling passage, the second cooling passage and the stator; In the magnet cooling flow path, the direction of the flow of the cooling gas in the axial direction is different at the same position in the axial direction.

According to the rotary electric machine disclosed in the present application, a stator provided between a stator coil and a stator magnet and having a stator magnet cooling passage penetrating in the axial direction, a first rotor, a second rotor, wherein the first through hole of the first end plate of the first rotor is located between the cylindrical first main body portion of the first rotor and the second rotor; and a first cooling channel communicating with a second through hole of a second end plate of the first rotor is formed, and a second cooling channel is formed between the first main body and the stator, In the first cooling passage, the second cooling passage, and the stator magnet cooling passage, the direction of flow of the cooling gas in the axial direction differs at the same position in the axial direction. It is possible to suppress the expansion of temperature distribution variation and temperature rise occurring in the second rotor. Since the expansion of variations in the temperature distribution and the temperature rise occurring in the first rotor and the second rotor are suppressed, the temperature rise during operation of the rotating electrical machine is suppressed, so that the output of the rotating electrical machine can be increased. can.

1 is a schematic diagram showing a cross section of a rotating electric machine according to Embodiment 1; FIG. 1 is a schematic diagram showing a main part of a rotating electric machine according to Embodiment 1; FIG. 4 is a schematic diagram showing another cross section of the rotating electric machine according to Embodiment 1. FIG. 2 is a schematic diagram showing a low-speed rotor of the rotary electric machine according to Embodiment 1; FIG. FIG. 4 is a schematic diagram showing another low-speed rotor of the rotary electric machine according to Embodiment 1; 1 is a schematic diagram showing a main part of a housing of a rotating electric machine according to Embodiment 1; FIG. 4 is a schematic diagram showing a main part of another casing of the rotary electric machine according to Embodiment 1; FIG. 4 is a schematic diagram showing a cross section of another rotating electric machine according to the first embodiment; FIG. FIG. 7 is a schematic diagram showing a cross section of a rotating electrical machine according to Embodiment 2; FIG. 9 is a schematic diagram showing a cross section of another rotating electric machine according to Embodiment 2; FIG. 7 is a schematic diagram showing a cross section of a rotating electric machine according to Embodiment 3; FIG. 11 is a schematic diagram showing a cross section of another rotating electric machine according to Embodiment 3; FIG. 11 is a schematic diagram showing a cross section of another rotating electric machine according to Embodiment 3; FIG. 11 is a schematic diagram showing a cross section of a rotating electric machine according to Embodiment 4; FIG. 11 is a schematic diagram showing a cross section of another rotating electric machine according to Embodiment 4; FIG. 11 is a schematic diagram showing a cross section of a rotating electric machine according to Embodiment 5; FIG. 11 is a schematic diagram showing a main part of a rotating electric machine according to Embodiment 5; FIG. 11 is a schematic diagram showing a low-speed rotor of a rotary electric machine according to Embodiment 5; FIG. 12 is a schematic diagram showing another low-speed rotor of the rotary electric machine according to Embodiment 5; FIG. 11 is a schematic diagram showing a main part of a casing of a rotating electric machine according to Embodiment 5; FIG. 12 is a schematic diagram showing a main part of another casing of the rotary electric machine according to Embodiment 5; FIG. 11 is a schematic diagram showing a cross section of another rotating electric machine according to Embodiment 5;

A rotating electric machine according to an embodiment of the present application will be described below with reference to the drawings. In each figure, the same or corresponding members and parts are denoted by the same reference numerals.

Embodiment 1.
FIG. 1 is a schematic diagram showing a cross section of rotating electric machine 100 according to Embodiment 1, and is a diagram showing a cross section perpendicular to rotating shaft 40. FIG. 2 is a schematic diagram showing a main part of rotating electric machine 100. FIG. 3 is a schematic diagram showing another cross section of the rotating electric machine 100, cut along the AA cross section of FIG. 1, and FIG. FIG. 5 is a schematic diagram showing the rotor 20 portion, showing the first end plate 22a side, and FIG. 5 is a schematic diagram showing another low-speed rotor 20 portion of the rotary electric machine 100, showing the first end plate 22a side. FIG. 6 is a schematic diagram showing a main part of the casing 45 of the rotating electrical machine 100, showing the first inner wall 45b, and FIG. FIG. 8 is a diagram showing the first inner wall 45b, and FIG. 8 is a schematic diagram showing a cross section of another rotating electric machine 100 according to Embodiment 1, cut at the same position as in FIG. The rotating electric machine 100 in the present application is a rotating electric machine known as a magnetic geared generator, which includes a stator 10, a low speed rotor 20 as a first rotor, and a high speed rotor 30 as a second rotor. is.

<Rotating electric machine 100>
As shown in FIG. 1 , the rotating electric machine 100 includes a rotating shaft 40 that is the center of rotation of the rotating electric machine 100 , an annular stator 10 that surrounds the rotating shaft 40 , and a stator 10 that is coaxial with the stator 10 inside the stator 10 . and a high-speed rotor 30 provided coaxially with the low-speed rotor 20 facing the inner side of the low-speed rotor 20 . First, the general structure and operation of rotating electric machine 100 will be described.

The stator 10 includes a stator core 13, stator coils 11, and stator magnets 12, as shown in FIG. The annular stator core 13 includes a plurality of stator slots 13a and stator teeth 13b that are open radially inward with respect to the rotating shaft 40 and are alternately spaced in the circumferential direction. A plurality of stator slots 13 a each comprise a stator coil 11 and a stator magnet 12 . The stator coil 11 is arranged on the bottom side of the stator slot 13a. The stator magnets 12 are arranged on the open side of the stator slots 13a. The stator magnets 12 are magnetized to have the same magnetic pole direction in the radial direction. The stator magnet 12 is, for example, a neodymium sintered magnet, but is not limited to this. If the inner diameter side of the stator magnet 12 is the N pole, the inner diameter side of the adjacent stator teeth 13b is the S pole, forming the same number of pole pairs Ns as the number of the stator slots 13a. A stator magnet cooling channel 15 , which is a first stator cooling portion, is provided between the stator coil 11 and the stator magnet 12 . The stator magnet cooling flow path 15 is provided to penetrate in the axial direction. The stator coil 11 and the stator magnet 12 face each other with the stator magnet cooling flow path 15 interposed therebetween. The stator coils 11 and the stator magnets 12 are fixed, for example, by bonding them to the wall surfaces of the stator slots 13a, but the fixing method is not limited to this. The cooling gas passages of the stator 10 and the like will be described later.

The low-speed rotor 20 is provided coaxially with the stator 10 via a narrow first gap 61 on the inner peripheral side of the stator 10 so as to face the stator magnets 12 . The low-speed rotor 20 rotates integrally with the rotating shaft 40 . The low-speed rotor 20 has a cylindrical first body portion 26 and a plurality of magnetic pole pieces 21 circumferentially spaced apart on the first body portion, and is rotated at a low speed by external power. . In this embodiment, the pole pieces 21 are evenly spaced. Let NL be the number of the pole pieces 21 . The pole piece 21 is secured to the first body portion 26 via an insulating material 25 . The pole piece 21 and the first body portion 26 are insulated.

The high-speed rotor 30 is provided coaxially with the low-speed rotor 20 via a narrow second gap 62 so as to face the radially inner wall surface of the first body portion 26 . The high-speed rotor 30 has a cylindrical second body portion 35 and high-speed rotor magnets 31, which are a plurality of permanent magnets arranged at intervals in the circumferential direction on the outer peripheral portion of the second body portion 35. , Nh are formed. In this embodiment, the high-speed rotor magnets 31 are arranged at regular intervals. Each size of the first gap 61 and the second gap 62 is, for example, several millimeters.

If the relationship among Ns, NL, and Nh satisfies NL=Ns±Nh, the magnetic interaction between the stator magnet 12 and the high-speed rotor magnet 31 generates negative torque in the low-speed rotor 20 . On the other hand, by rotating the low-speed rotor 20 with external power, an input can be obtained to the low-speed rotor 20 . If a stator current is passed through the stator coil 11 so as to free-run the high-speed rotor 30 with respect to the input of the low-speed rotor 20, the high-speed rotor 30 rotates at a rotational speed NL/Nh times that of the low-speed rotor 20. Rotate. When the high-speed rotor 30 rotates at NL/Nh times the speed of the low-speed rotor 20 , an induced electromotive force is generated in the stator coil 11 . Generated power is output from the stator coil 11 due to the generation of the induced electromotive force.

Next, other components included in the rotating electrical machine 100 will be described. The rotary electric machine 100 includes a fan 43, a heat exchanger 44, and a housing 45 that houses the stator 10, the low speed rotor 20, and the high speed rotor 30, as shown in FIG. The fan 43 is arranged inside the housing 45 and sends out cooling gas. The heat exchanger 44 is arranged inside the housing 45, and the cooling gas sent out from the fan 43 passes through it. The cooling gas circulates inside the housing 45, and a portion through which the cooling gas passes serves as a flow path for the cooling gas. Further, when the rotating electric machine 100 is applied to an offshore wind turbine generator, a turbine blade 41 is attached to a rotating shaft 40 protruding outside the rotating electric machine 100 .

The housing 45 includes a peripheral wall 45a, a first inner wall 45b, a second inner wall 45c, a first outer wall 45d, and a second outer wall 45e. The peripheral wall 45a surrounds the stator 10 from the radial outside. The first inner wall 45b is connected to the peripheral wall 45a and covers one side of the stator 10, the low speed rotor 20 and the high speed rotor 30 in the axial direction. The second inner wall 45c is connected to the peripheral wall 45a and covers the other side of the stator 10, the low speed rotor 20 and the high speed rotor 30 in the axial direction. 45 d of 1st outer walls are connected with the surrounding wall 45a, and cover the axial direction one side of the 1st inner wall 45b at intervals. The second outer wall 45e is connected to the peripheral wall 45a and covers the other axial side of the second inner wall 45c with a space therebetween. Each of the first inner wall 45b, the second inner wall 45c, and the second outer wall 45e is connected to the rotating shaft 40 via the bearing 42. As shown in FIG.

<Cooling Gas Flow Path of Rotary Electric Machine 100>
A cooling gas flow path formed inside rotating electric machine 100 will be described. Along with the description of the flow path, each part where the flow path is formed will be described. The first body portion 26 has a first end plate 22a and a second end plate 22b. The first end plate 22 a extends radially inward from one axial end of the first body portion 26 between the high-speed rotor 30 and the first inner wall 45 b in the axial direction, and is fixed to the rotating shaft 40 . be done. The second end plate 22 b extends radially inward from the other axial end of the first body portion 26 between the high-speed rotor 30 and the second inner wall 45 c in the axial direction, and is fixed to the rotating shaft 40 . be done. The first end plate 22a has a first through hole 23a axially penetrating in its radially outer portion. The second end plate 22b has a second through hole 23b axially penetrating in a radially outer portion. These through-holes are formed radially outward of 3/4 of the radius of each end plate. Each through hole is a portion not hatched in FIG. In the following cross-sectional views as well, the through-holes provided in each part are shown as non-hatched portions.

A first cooling passage 71 communicating with the first through hole 23 a and the second through hole 23 b is formed between the first main body portion 26 and the high-speed rotor 30 to provide a cooling path between the first main body portion 26 and the stator 10 . A second cooling channel 72 is formed therebetween. The first cooling channel 71 is part of the second gap 62 and the second cooling channel 72 is part of the first gap 61 .

The first inner wall 45b communicates with the first cooling channel 71 and communicates with the first inner wall inner through-hole 47a penetrating in the axial direction, the second cooling channel 72 and the stator magnet cooling channel 15, and communicates with the first cooling channel 71. It has a first inner wall outer through hole 47b that penetrates in the axial direction at a radial position radially outer than the inner wall inner through hole 47a. The second inner wall 45c communicates with the first cooling channel 71 and communicates with the second inner wall inner through-hole 48a extending axially therethrough, the second cooling channel 72 and the stator magnet cooling channel 15, and communicates with the second cooling channel 71. It has a second inner wall outer through hole 48b that penetrates in the axial direction at a radial position radially outer than the inner wall inner through hole 48a.

Between the first inner wall 45b and the first outer wall 45d, a one side wall flow passage 73 for the cooling gas is formed to communicate between the first inner wall outer through hole 47b and the first inner wall inner through hole 47a. Between the inner wall 45c and the second outer wall 45e, another side wall inner flow passage 74 for the cooling gas is formed, which communicates between the second inner wall outer through-hole 48b and the second inner wall inner through-hole 48a.

The fan 43 is arranged in one or both of the first inner wall 45b and the first outer wall 45d and the second inner wall 45c and the second outer wall 45e. The heat exchanger 44 is arranged in one or both of the first inner wall 45b and the first outer wall 45d and the second inner wall 45c and the second outer wall 45e. In this embodiment, the fan 43 is arranged inside the one side wall inner channel 73 and sends out cooling gas. The heat exchanger 44 is arranged inside the other side wall inner channel 74 . The arrangement of the fan 43 and the heat exchanger 44 is not limited to this, and the arranged flow paths may be reversed. When the fan 43 and the heat exchanger 44 are arranged in separate flow paths, the fan 43 and the heat exchanger 44 can be fixed to the respective flow paths without interfering with each other when the rotating electrical machine 100 is manufactured. productivity can be improved. Further, as shown in FIG. 8, the fan 43 and the heat exchanger 44 may be arranged inside the one side wall inner channel 73 . When the fan 43 and the heat exchanger 44 are arranged in the same channel 73 , the fan 43 and the heat exchanger 44 can be gathered on the side opposite to the turbine blades 41 . can be reduced in size.

The flow of cooling gas will be described with reference to FIG. The cooling gas sent out from the fan 43 passes through the first cooling channel 71, the other side wall inner channel 74, the second cooling channel 72, the stator magnet cooling channel 15, the one side wall inner channel, as indicated by the arrows. It flows in the order of 73. The cooling gas passes through the heat exchanger 44 in the other side wall inner channel 74 . FIG. 3 shows two types of arrows. An arrow 51 with a circle on the side opposite to the arrow indicates the flow of the cooling gas whose temperature is relatively low due to heat dissipation in the heat exchanger 44 . An arrow 52 with a square on the side opposite to the arrow indicates the flow of cooling gas whose temperature is relatively high due to the heat received from each part. In the first cooling channel 71, the second cooling channel 72, and the stator magnet cooling channel 15, the cooling gas flows in different axial directions at the same position in the axial direction. The direction in which the cooling gas flows is not limited to this, and the cooling gas may flow in the opposite direction. Even if the cooling gas flows in the opposite direction, in the first cooling passage 71, the second cooling passage 72, and the stator magnet cooling passage 15, at the same position in the axial direction, the cooling gas flows in the axial direction. is different.

Effects obtained by the flow of the cooling gas described above will be described. The magnetic pole pieces 21 generate heat as the rotating electric machine 100 operates. The heat generated by the pole pieces 21 is transferred to the insulating material 25, which heats up. The insulating material 25 has a predetermined allowable temperature, and if the allowable temperature is exceeded, the insulating performance may deteriorate and the life may be shortened. One of the measures for mitigating the temperature rise of the insulating material 25 is to increase the amount of circulating air in the rotating electric machine 100 . However, since the first gap 61 and the second gap 62 are very narrow, a large fan is required to secure the necessary air volume. Installation of a large fan poses a problem in terms of cost performance. In the case of a ventilation system in which the cooling gas flows in the same direction in the first gap 61 and the second gap 62, the temperature of the cooling gas in both the first gap 61 and the second gap 62 is lower on the upstream side and lower on the downstream side. temperature rises, it is inefficient to reduce the maximum temperature of the low-speed rotor 20 .

By configuring the flow of the cooling gas as shown in FIG. 3 or 8, the cooling gas flows in opposite directions in the first gap 61 and the second gap 62, so that the maximum temperature of the low-speed rotor 20 can be efficiently reduced. be able to. In addition, it is possible to suppress an increase in temperature distribution variation and a temperature rise occurring in the low-speed rotor 20 and the high-speed rotor 30 . Moreover, since the maximum temperature of the low-speed rotor 20 can be reduced while avoiding an increase in size of the fan, problems caused by the insulating material 25 of the low-speed rotor 20 can be suppressed. Since defects of the insulating material 25 are suppressed, the reliability of the rotating electric machine 100 can be improved. Further, if the bottleneck of the output of rotating electrical machine 100 is the temperature of low-speed rotor 20, the temperature rise during operation of rotating electrical machine 100 is suppressed, so the output of rotating electrical machine 100 can be increased. Moreover, since the cooling gas also flows through the stator magnet cooling passages 15 formed in the stator 10, the stator 10 can also be efficiently cooled.

Since FIGS. 3 and 8 are sectional views, only one first through hole 23a of the first end plate 22a and one second through hole 23b of the second end plate 22b are shown. The numbers of 23a and second through holes 23b are not limited to one. As shown in FIG. 4, a plurality of first through holes 23a may be provided at intervals. Further, the shape of each of the first through-holes 23a and the second through-holes 23b is not limited to a circular shape, and as shown in FIG. Any shape is acceptable. Although only the example of the first end plate 22a is shown, the same applies to the second through hole 23b of the second end plate 22b.

Since FIGS. 3 and 8 are cross-sectional views, only one first inner wall through-hole 47a, first inner wall outer through-hole 47b, second inner wall inner through-hole 48a, and second inner wall outer through-hole 48b are provided. Although shown, the number of first inner wall inner through-holes 47a, first inner wall outer through-holes 47b, second inner wall inner through-holes 48a, and second inner wall outer through-holes 48b is not limited to one. As shown in FIG. 6, a plurality of first inner wall through holes 47a and first inner wall outer through holes 47b may be provided at intervals. Further, the shape of each of the first inner wall inner through-hole 47a, the first inner wall outer through-hole 47b, the second inner wall inner through-hole 48a, and the second inner wall outer through-hole 48b is not limited to a circular shape, and is shown in FIG. , a shape in which a plurality of through-holes are connected along the outer circumference of the first inner wall 45b may be used. Although only an example of the first inner wall 45b is shown, the same applies to the second inner wall inner through-hole 48a and the second inner wall outer through-hole 48b of the second inner wall 45c. Also, the number of fans 43 and heat exchangers 44 is not limited to one. For example, fans 43 may be provided at respective positions corresponding to a plurality of first inner wall inner through holes 47a.

<Baffle>
The rotary electric machine 100 may be provided with a baffle that suppresses the flow of cooling gas in the radial direction. If the parts of the rotary electric machine 100 are close to each other in the axial direction, the baffles may not be provided because the cooling gas is less likely to flow in the radial direction without providing the baffles. If the respective parts of the rotating electric machine 100 are not close to each other in the axial direction, it is possible to suppress the flow of the cooling gas in the radial direction by providing the baffles. By suppressing the flow of the cooling gas in the radial direction, the cooling gas can efficiently flow through the first cooling channel 71 , the second cooling channel 72 , and the stator magnet cooling channel 15 .

The configuration of the baffle will be explained. The baffle is made of metal or resin, for example. The first baffle 46a is formed in a cylindrical shape, and is arranged radially inward of the first through hole 23a between the one axial side of the high-speed rotor 30 and the first end plate 22a. Coaxially provided. The second baffle 46b is formed in a cylindrical shape, and is arranged radially inward of the second through hole 23b between the other axial side of the high-speed rotor 30 and the second end plate 22b. Coaxially provided. The first baffle 46a is fixed to the high speed rotor 30 or the first end plate 22a. The second baffle 46b is fixed to the high speed rotor 30 or the second end plate 22b.

The third baffle 46c is formed in a cylindrical shape, and is radially inward of the first inner wall inner through-hole 47a and the first through-hole 23a between the one axial side of the first end plate 22a and the first inner wall 45b. , and provided coaxially with the stator 10 . The fourth baffle 46d is formed in a cylindrical shape, and is radially inward of the second inner wall inner through hole 48a and the second through hole 23b between the other axial side of the second end plate 22b and the second inner wall 45c. , and provided coaxially with the stator 10 . The third baffle 46c is fixed to the first end plate 22a or the first inner wall 45b. A fourth baffle 46d is fixed to the second end plate 22b or the second inner wall 45c.

The fifth baffle 46e is formed in a cylindrical shape, and is located radially inward of the first inner wall outer through-hole 47b between the end surface of the low-speed rotor 20 on one axial side and the first inner wall 45b. It is arranged radially outside the hole 23 a and the first inner wall inner through-hole 47 a and provided coaxially with the stator 10 . The sixth baffle 46f is formed in a cylindrical shape, and is located radially inward of the second inner wall outer through-hole 48b between the end surface of the low-speed rotor 20 on the other axial side and the second inner wall 45c. It is arranged radially outside of the hole 23b and the second inner wall inner through-hole 48a and provided coaxially with the stator 10 . A fifth baffle 46e is fixed to the first end plate 22a or the first inner wall 45b, and a sixth baffle 46f is fixed to the second end plate 22b or the second inner wall 45c.

As described above, the rotating electric machine 100 according to Embodiment 1 includes the stator 10 having the stator magnet cooling passage 15 provided between the stator coil 11 and the stator magnet 12 and penetrating in the axial direction. , a low-speed rotor 20 and a high-speed rotor 30, and between the cylindrical first body portion 26 of the low-speed rotor 20 and the high-speed rotor 30, the first through hole 23a of the first end plate 22a and the A first cooling channel 71 communicating with the second through hole 23b of the second end plate 22b is formed, and a second cooling channel 72 is formed between the first main body portion 26 and the stator 10 to provide a first cooling Since the flow path 71, the second cooling flow path 72, and the stator magnet cooling flow path 15 have different axial directions in which the cooling gas flows at the same position in the axial direction, the low-speed rotor 20 and the high-speed rotation are controlled. It is possible to suppress the expansion of variations in temperature distribution and temperature rise occurring in the element 30 . Since the increase in temperature distribution variation and temperature rise occurring in the low-speed rotor 20 and the high-speed rotor 30 are suppressed, the temperature rise during operation of the rotating electrical machine 100 is suppressed, so that the output of the rotating electrical machine 100 can be increased. can. Moreover, since the cooling gas also flows through the stator magnet cooling passages 15 formed in the stator 10, the stator 10 can also be efficiently cooled.

A first baffle 46a arranged radially inside the first through hole 23a and provided coaxially with the stator 10, and a first baffle 46a arranged radially inside the second through hole 23b and provided coaxially with the stator 10. When the second baffle 46b is provided, it is possible to suppress the flow of the cooling gas in the radial direction, so that the cooling gas can efficiently flow through the first cooling flow path 71 . Further, a third baffle 46c arranged radially inward of the first inner wall inner through hole 47a and the first through hole 23a and provided coaxially with the stator 10, a second inner wall inner through hole 48a and the second through hole 46c If the fourth baffle 46d is arranged radially inward of the hole 23b and provided coaxially with the stator 10, it is possible to suppress the flow of the cooling gas in the radial direction. The cooling gas can be efficiently flowed to 71 . a fifth baffle 46e arranged radially inside the first inner wall outer through hole 47b and radially outer than the first through hole 23a and the first inner wall inner through hole 47a and provided coaxially with the stator 10; and a sixth baffle 46f arranged radially inside the second inner wall outer through hole 48b and radially outer than the second through hole 23b and the second inner wall inner through hole 48a and provided coaxially with the stator 10 , the cooling gas can be suppressed from flowing in the radial direction. be able to.

Between the first inner wall 45b and the first outer wall 45d, a one side wall flow path 73 for communicating the cooling gas between the first inner wall outer through hole 47b and the first inner wall inner through hole 47a is formed. is arranged inside the one side wall inner flow path 73, and the cooling gas communicates between the second inner wall outer through hole 48b and the second inner wall inner through hole 48a between the second inner wall 45c and the second outer wall 45e. is formed, and the heat exchanger 44 is arranged inside the other side wall inner flow path 74, the fan 43 and the heat exchanger 44 do not interfere with each other when the rotating electric machine 100 is manufactured. Since it can be fixed to each flow path, the productivity of rotating electric machine 100 can be improved.

Between the first inner wall 45b and the first outer wall 45d, a one side wall flow path 73 for communicating the cooling gas between the first inner wall outer through hole 47b and the first inner wall inner through hole 47a is formed. and the heat exchanger 44 is arranged inside the one side wall inner channel 73, between the second inner wall 45c and the second outer wall 45e, between the second inner wall outer through hole 48b and the second inner wall inner through hole 48a When the other side wall inner flow path 74 for the cooling gas communicating with is formed, the size of the rotating electric machine 100 in the axial direction can be reduced.

Embodiment 2.
A rotating electric machine 100 according to Embodiment 2 will be described. FIG. 9 is a schematic diagram showing a cross section of the rotating electrical machine 100 according to the second embodiment, taken at a position equivalent to the AA cross section position in FIG. 1, and FIG. 10 shows another rotating electrical machine according to the second embodiment. It is a schematic diagram which shows the cross section of 100. FIG. A rotating electric machine 100 according to Embodiment 2 is configured such that a stator core 13 has a stator core cooling flow path 14 that is a second stator cooling portion.

The stator core 13 is provided radially outside the stator coil 11 and has a stator core cooling passage 14 that penetrates in the axial direction. The first inner wall 45b has a first inner wall outer second through hole 47c that communicates with the stator core cooling flow path 14 and penetrates in the axial direction at a radial position radially outer than the first inner wall outer through hole 47b. . The second inner wall 45c communicates with the stator core cooling passage 14 and has a second inner wall outer second through hole 48c axially penetrating at a radial position radially outer than the second inner wall outer through hole 48b. .

One of the cooling gases communicating between the first inner wall outer through-hole 47b and the first inner wall outer second through-hole 47c and the first inner wall inner through-hole 47a between the first inner wall 45b and the first outer wall 45d A sidewall inner channel 73 is formed. Between the second inner wall 45c and the second outer wall 45e, the other of the cooling gas communicating between the second inner wall outer through-hole 48b and the second inner wall outer second through-hole 48c and the second inner wall inner through-hole 48a A sidewall inner channel 74 is formed. The fan 43 is arranged inside the one side wall inner channel 73 and sends out cooling gas. The heat exchanger 44 is arranged inside the other side wall inner channel 74 . The arrangement of the fan 43 and the heat exchanger 44 is not limited to this, and the arranged flow paths may be reversed.

The flow of cooling gas will be described with reference to FIG. The cooling gas sent out from the fan 43 flows through the first cooling flow path 71, the other side wall inner flow path 74, the second cooling flow path 72, the stator magnet cooling flow path 15, and the stator core cooling flow, as indicated by the arrows. It flows in the order of channel 14 and one side wall channel 73 . The cooling gas passes through the heat exchanger 44 in the other side wall inner channel 74 . In the first cooling flow path 71, the second cooling flow path 72, the stator magnet cooling flow path 15, and the stator core cooling flow path 14, at the same position in the axial direction, the axial direction in which the cooling gas flows is different. The direction in which the cooling gas flows is not limited to this, and the cooling gas may flow in the opposite direction. Even if the cooling gas flows in the opposite direction, the first cooling passage 71, the second cooling passage 72, the stator magnet cooling passage 15, and the stator core cooling passage 14 are arranged at the same position in the axial direction. , the axial directions of cooling gas flow are different.

With this configuration, the radially outer side of the stator 10 can be efficiently cooled by the stator core cooling passages 14 . Since the radially outer side of the stator 10 can be efficiently cooled, it is possible to suppress the increase in the variation in the radial temperature distribution of the stator 10 . The radial inner side of the stator 10 is efficiently cooled by the stator magnet cooling flow path 15 .

A baffle may be added to the rotary electric machine 100 . The first stator baffle 46g is located between the one axial side of the stator core 13 and the first inner wall 45b, radially inward of the stator core cooling flow path 14 and the first inner wall outer second through hole 47c. Moreover, it is arranged radially outside the first inner wall outer through-hole 47 b and provided coaxially with the stator 10 . The second stator baffle 46h is located between the other axial side of the stator core 13 and the second inner wall 45c, radially inward of the stator core cooling flow path 14 and the second inner wall outer second through hole 48c. Moreover, it is arranged radially outside the second inner wall outer through-hole 48 b and provided coaxially with the stator 10 . A first stator baffle 46g is fixed to the stator 10, the first inner wall 45b, or both. A second stator baffle 46h is fixed to the stator 10, the second inner wall 45c, or both. By configuring in this way, it is possible to suppress the flow of the cooling gas in the radial direction, so that the cooling gas can efficiently flow through the stator core cooling flow path 14 .

Incidentally, as shown in FIG. 10, the fan 43 and the heat exchanger 44 may be arranged inside the one side wall inner channel 73 . When the fan 43 and the heat exchanger 44 are arranged in the same flow path, the fan 43 and the heat exchanger 44 can be concentrated on the side opposite to the turbine blades 41, so that the size of the rotary electric machine 100 in the axial direction can be reduced. can be done.

As described above, in the rotating electrical machine 100 according to Embodiment 2, the stator core 13 is provided radially outside the stator coils 11 and has the stator core cooling flow path 14 penetrating in the axial direction. Since the radially outer side of the stator 10 can be efficiently cooled by the stator core cooling passages 14, it is possible to suppress the increase in the radial temperature distribution variation of the stator 10 and the temperature rise. Since the increase in variation in temperature distribution and the temperature rise occurring in the stator 10 are suppressed, the temperature rise during operation of the rotating electrical machine 100 is suppressed, so the output of the rotating electrical machine 100 can be increased.

One of the cooling gases communicating between the first inner wall outer through-hole 47b and the first inner wall outer second through-hole 47c and the first inner wall inner through-hole 47a between the first inner wall 45b and the first outer wall 45d A side wall inner channel 73 is formed, the fan 43 and the heat exchanger 44 are arranged inside one side wall channel 73, and a second inner wall outer through hole 48b is formed between the second inner wall 45c and the second outer wall 45e. and the second inner wall outer second through-hole 48c and the second inner wall inner through-hole 48a are formed to communicate with each other. can be made smaller.

The stator core cooling flow path 14 and the first inner wall outer second through hole 47c are arranged radially inward, and the first inner wall outer through hole 47b is arranged radially outward. The stator baffle 46g is arranged radially inward of the stator core cooling passage 14 and the second inner wall outer second through hole 48c and radially outer than the second inner wall outer through hole 48b. When the second stator baffle 46h is provided coaxially with the second stator baffle 46h, it is possible to suppress the flow of the cooling gas in the radial direction. .

Embodiment 3.
A rotating electrical machine 100 according to Embodiment 3 will be described. FIG. 11 is a schematic diagram showing a cross section of the rotating electric machine 100 according to the third embodiment, taken at a position equivalent to the AA cross section position in FIG. 1, and FIG. 12 shows another rotating electric machine according to the third embodiment. 13 is a schematic diagram showing a cross section of another rotary electric machine 100 according to the third embodiment. Regarding the portion of the stator 10, the radially inner side shows the section of the stator slot 13a, and the radially outer side shows the section of the stator teeth 13b. A rotary electric machine 100 according to Embodiment 3 has a configuration in which a stator 10 and a low-speed rotor 20 are provided with a ventilation passage extending radially therethrough.

The stator core 13 radially penetrates between the second cooling flow path 72 and the stator core cooling flow path 14 at the center in the axial direction of the stator core 13 and is fixed to the second cooling flow path 72 . It has a stator air passage 16 connecting the child core cooling passage 14 and the stator magnet cooling passage 15 . The stator ventilation passages 16 are formed in the stator teeth 13b, as shown in FIG. The first main body portion 26 radially penetrates between the first cooling flow path 71 and the second cooling flow path 72 at the center portion in the axial direction of the first main body portion 26 . It has a low-speed rotor ventilation passage 24 which is a first rotor ventilation passage communicating with the second cooling passage 72 . The number of stator ventilation paths 16 is not limited to one. The stator ventilation path 16 may be provided in each of the stator teeth 13b at different positions in the circumferential direction. Similarly, a plurality of low-speed rotor ventilation passages 24 may be provided at different positions in the circumferential direction of the first body portion 26 .

Between the first inner wall 45b and the first outer wall 45d, one side first wall inner channel 80a communicating with the first inner wall inner through hole 47a and one side first wall channel 80a communicating with the first inner wall outer second through hole 47c are provided. Two-wall inner channel 80b, one-side first-wall inner channel 80a, one-side second-wall inner channel 80b, and one-side third-wall inner channel 80c communicating with first inner-wall-outer through-hole 47b. It is formed. Between the second inner wall 45c and the second outer wall 45e, the other side first wall inner channel 81a communicating with the second inner wall inner through hole 48a and the other side first wall channel 81a communicating with the second inner wall outer second through hole 48c are provided. The two-wall inner channel 81b and the other-side third-wall inner channel 81c communicating the other-side first-wall inner channel 81a and the other-side second-wall inner channel 81b with the second inner-wall outer through-hole 48b. It is formed.

A first fan 43a, which is the fan 43, and a first heat exchanger 44a, which is the heat exchanger 44, are arranged in the one-side third wall inner flow path 80c. A second fan 43b, which is the fan 43, and a second heat exchanger 44b, which is the heat exchanger 44, are arranged in the other side third wall inner flow path 81c.

The first fan 43a sends cooling gas toward the first inner wall outer through-hole 47b, and the second fan 43b sends cooling gas toward the second inner wall outer through-hole 48b. Arrows 51 and 52 shown in FIG. 11 indicate the flow of cooling gas in this case. The flow of the cooling gas is not limited to this. The first fan 43a sends the cooling gas toward the side opposite to the side of the first inner wall outer through-hole 47b, and the second fan 43b blows the second inner wall. The cooling gas may be sent out toward the side opposite to the side of the outer through hole 48b. In this case, the cooling gas flows in the opposite direction to the arrows shown in FIG.

The flow of cooling gas will be described with reference to FIG. Two flow paths are formed from the cooling gas sent from the first fan 43a. One is the second cooling channel 72, the low-speed rotor ventilation channel 24, the first cooling channel 71, the one-side first-wall inner channel 80a, and the one-side third-wall inner channel 80c. The other is the second cooling channel 72 and the stator magnet cooling channel 15, the stator ventilation channel 16, the stator core cooling channel 14, the one side second wall inner channel 80b, the one side third wall inner It flows in order of the flow path 80c. Two flow paths are also formed from the cooling gas sent out from the second fan 43b. One is the second cooling channel 72, the low-speed rotor ventilation channel 24, the first cooling channel 71, the other side first wall inner channel 81a, and the other side third wall inner channel 81c in this order. The other is the second cooling channel 72, the stator magnet cooling channel 15, the stator ventilation channel 16, the stator core cooling channel 14, the other side second wall inner channel 81b, the other side third wall inner It flows in order of the flow path 81c. The cooling gas passes through the first heat exchanger 44a in the one-side third-wall inner channel 80c and passes through the second heat exchanger 44b in the other-side third-wall inner channel 81c. In the first cooling channel 71 and the stator core cooling channel 14, and the second cooling channel 72 and the stator magnet cooling channel 15, the cooling gas flows in different axial directions at the same position in the axial direction. ing.

With this configuration, the first cooling channel 71, the stator core cooling channel 14, the second cooling channel 72, and Since the cooling gas flows in opposite directions in the respective portions of the stator magnet cooling flow path 15, it is possible to suppress the increase in variation in temperature distribution and temperature rise occurring in the low-speed rotor 20, the high-speed rotor 30, and the stator 10. can. Since the increase in temperature distribution variation and temperature rise occurring in the low-speed rotor 20, the high-speed rotor 30, and the stator 10 is suppressed, the temperature rise during operation of the rotating electrical machine 100 is suppressed, so that the output of the rotating electrical machine 100 is suppressed. can be increased.

12, the stator magnet 12 radially penetrates between the second cooling passage 72 and the stator magnet cooling passage 15 at the axial center of the stator magnet 12. , the stator magnet ventilation passage 16a that communicates the second cooling passage 72 and the stator magnet cooling passage 15, and the stator magnet ventilation passage 16a communicates with the low-speed rotor ventilation passage 24. good too. By configuring in this way, the number of flow paths for the cooling gas flowing in the radial direction is increased, so the cooling gas can be made to flow easily in the second cooling flow path 72 and the stator magnet cooling flow path 15 .

In FIG. 12, the first heat exchanger 44a is arranged on one axial side of the first fan 43a, and the second heat exchanger 44b is arranged on the other axial side of the second fan 43b. These arrangements are not limited to this, but as shown in FIG. 13, the first heat exchanger 44a is arranged on the other side in the axial direction of the first fan 43a, The second heat exchanger 44b may be arranged in .

As described above, in the rotating electrical machine 100 according to Embodiment 3, the stator core 13 is arranged between the second cooling flow path 72 and the stator core cooling flow path 14 at the central portion in the axial direction of the stator core 13. It has a stator ventilation passage 16 that radially penetrates and communicates with the second cooling passage 72, the stator core cooling passage 14, and the stator magnet cooling passage 15, and the first main body portion 26 is the first main body. At the center in the axial direction of the portion 26, the first cooling channel 71 and the second cooling channel 72 are penetrated in the radial direction, and the first cooling channel 71 and the second cooling channel 72 are communicated with each other. Since the low-speed rotor air passage 24, which is the first rotor air passage, is provided, the first cooling passage 71 and the stator core cooling flow on both axial sides of the stator air passage 16 and the low-speed rotor air passage 24 Since the cooling gas flows in opposite directions in the respective portions of the passage 14, the second cooling passage 72 and the stator magnet cooling passage 15, the temperature distribution produced in the low speed rotor 20, the high speed rotor 30 and the stator 10 is It is possible to suppress the expansion of the variation of the temperature and the temperature rise. Since the increase in temperature distribution variation and temperature rise occurring in the low-speed rotor 20, the high-speed rotor 30, and the stator 10 is suppressed, the temperature rise during operation of the rotating electrical machine 100 is suppressed, so that the output of the rotating electrical machine 100 is suppressed. can be increased.

The stator magnet 12 radially penetrates between the second cooling flow path 72 and the stator magnet cooling flow path 15 at the axial center of the stator magnet 12 and is fixed to the second cooling flow path 72. If the stator magnet ventilation passage 16 a communicates with the child magnet cooling passage 15 , the number of passages for the cooling gas flowing in the radial direction is increased. Allows gas to flow easily.

Embodiment 4.
A rotating electrical machine 100 according to Embodiment 4 will be described. FIG. 14 is a schematic diagram showing a cross section of the rotating electrical machine 100 according to the fourth embodiment, taken at a position equivalent to the AA section position in FIG. 1, and FIG. 15 shows another rotating electrical machine according to the fourth embodiment. It is a schematic diagram which shows the cross section of 100. FIG. A rotary electric machine 100 according to Embodiment 4 has a configuration in which a high-speed rotor 30 has a flow path inside.

The second body portion 35 has a third end plate 32a and a fourth end plate 32b. The third end plate 32 a extends radially inward from one axial end of the second body portion 35 and is connected to the rotating shaft 40 via a bearing 42 . The fourth end plate 32 b extends radially inward from the other axial end of the second body portion 35 and is connected to the rotating shaft 40 via a bearing 42 . The third end plate 32a has a third through hole 33a penetrating in the axial direction. The fourth end plate 32b has a fourth through hole 33b that penetrates in the axial direction. A third cooling passage 75 is formed inside the high-speed rotor 30 to communicate with the third through-hole 33a and the fourth through-hole 33b. The high-speed rotor 30 radially penetrates between the first cooling passage 71 and the third cooling passage 75 at the axial center of the second main body portion 35 , and connects the first cooling passage 71 and the third cooling passage 75 . It has a high-speed rotor ventilation passage 34 that is a second rotor ventilation passage that communicates with the three cooling passages 75 . A plurality of high-speed rotor ventilation passages 34 may be provided at different positions in the circumferential direction of the high-speed rotor 30 .

The first end plate 22a has a first inner through-hole 23c that extends axially through the first through-hole 23a and communicates with the third through-hole 33a at a radially inner position relative to the first through-hole 23a. The second end plate 22b has a second inner through-hole 23d axially penetrating through the second through-hole 23b, communicating with the fourth through-hole 33b at a radially inner position of the second through-hole 23b. The first inner wall 45b has a first inner wall inner second through-hole 47d that communicates with the third cooling flow path 75 and penetrates in the axial direction at a radial position radially inner than the first inner wall inner through-hole 47a. The second inner wall 45c has a second inner wall inner second through hole 48d that communicates with the third cooling flow path 75 and penetrates in the axial direction at a radial position radially inner than the second inner wall inner through hole 48a.

Between the first inner wall 45b and the first outer wall 45d, there is a first one side wall inner flow path 82a for the cooling gas that communicates between the first inner wall inner through hole 47a and the first inner wall inner second through hole 47d. It is formed. Between the first inner wall 45b and the first outer wall 45d, a second one side wall inner flow path 82b for communicating between the first inner wall outer through hole 47b and the first inner wall outer second through hole 47c is provided. It is formed. Between the second inner wall 45c and the second outer wall 45e, a first other side wall inner channel 82c communicating between the second inner wall inner through hole 48a and the second inner wall inner second through hole 48d is formed. . Between the second inner wall 45c and the second outer wall 45e, a second other side wall inner flow path 82d is formed to communicate between the second inner wall outer through hole 48b and the second inner wall outer second through hole 48c. .

A first one-side fan 43c, which is the fan 43, and a first one-side heat exchanger 44c, which is the heat exchanger 44, are arranged in the first one-side wall inner channel 82a. A second one-side fan 43d, which is the fan 43, and a second one-side heat exchanger 44d, which is the heat exchanger 44, are arranged in the second one-side wall inner flow path 82b. The first other-side fan 43e, which is the fan 43, and the first other-side heat exchanger 44e, which is the heat exchanger 44, are arranged in the first other-side wall inner flow path 82c. A second other-side fan 43f, which is the fan 43, and a second other-side heat exchanger 44f, which is the heat exchanger 44, are arranged in the second other-side wall inner flow path 82d.

The first one-side fan 43c sends out cooling gas toward the first inner wall inner second through-hole 47d side, and the second one-side fan 43d directs the cooling gas toward the first inner wall outer through-hole 47b side. The other side fan 43e sends cooling gas toward the second inner wall inner second through hole 48d side, and the second other side fan 43f sends out cooling gas toward the second inner wall outer side through hole 48b side. Arrows 51 and 52 shown in FIG. 14 indicate the flow of cooling gas in this case. The flow of the cooling gas is not limited to this. 43d is directed to the side opposite to the side of the first inner wall outer through-hole 47b, and the first other side fan 43e is directed to the side opposite to the side of the second inner wall inner second through-hole 48d. The side fan 43f may send the cooling gas toward the side opposite to the side of the second inner wall outer through-hole 48b. In this case, the cooling gas flows in the opposite direction to the arrows shown in FIG.

The flow of cooling gas will be described with reference to FIG. The cooling gas sent out from the first one-side fan 43c passes through the third cooling channel 75, the high-speed rotor ventilation channel 34, the first cooling channel 71, the first one-side wall inner channel, as indicated by the arrows. 82a. The cooling gas sent out from the second one-side fan 43d passes through the second cooling passage 72, the stator magnet cooling passage 15, the stator air passage 16 and the stator magnet air passage 16a, the stator core cooling passage 14 , second one side wall inner channel 82b. The cooling gas sent out from the first other-side fan 43e flows through the third cooling channel 75, the high-speed rotor ventilation channel 34, the first cooling channel 71, and the first other-side wall inner channel 82c in this order. The cooling gas sent out from the second other-side fan 43f passes through the second cooling passage 72, the stator magnet cooling passage 15, the stator air passage 16 and the stator magnet air passage 16a, the stator core cooling passage 14 , second other side wall inner channel 82d.

In the first cooling channel 71 and the stator core cooling channel 14, and the second cooling channel 72, the stator magnet cooling channel 15 and the third cooling channel 75, at the same position in the axial direction, the cooling gas The axial direction of flow is different. A first cooling passage 71, a second cooling passage 72, a third cooling passage 75, and a stator on both axial sides of the stator air passage 16, the stator magnet air passage 16a, and the high-speed rotor air passage 34. The cooling gas flows in opposite directions in the respective parts of the magnet cooling channel 15 and the stator core cooling channel 14 .

By configuring in this way, the cooling gas flow path formed by one fan 43 can be shortened compared to the first and second embodiments. The main pressure loss that occurs in the cooling gas flow path inside rotating electric machine 100 is friction loss when the cooling gas passes through first cooling flow path 71 or second cooling flow path 72 having a small cross-sectional area. Since the passage of the cooling gas is shortened, the amount of boost required for one fan 43 can be reduced. Further, since the cooling gas also flows through the third cooling passage 75 formed in the high-speed rotor 30, the high-speed rotor 30 can be cooled more efficiently.

A baffle may be added to the rotary electric machine 100 . The seventh baffle 46i is formed in a cylindrical shape and extends radially inward from the third through hole 33a and the first inner through hole 23c between the one axial side of the high speed rotor 30 and the first end plate 22a. It is arranged and provided coaxially with the stator 10 . The eighth baffle 46j is formed in a cylindrical shape, and extends radially inward from the fourth through hole 33b and the second inner through hole 23d between the other axial side of the high speed rotor 30 and the second end plate 22b. It is arranged and provided coaxially with the stator 10 . The ninth baffle 46k is formed in a cylindrical shape, and has a larger diameter than the first inner through hole 23c and the first inner wall inner second through hole 47d between the one axial side of the low speed rotor 20 and the first inner wall 45b. It is arranged on the inner side of the direction and provided coaxially with the stator 10 . The tenth baffle 46l is formed in a cylindrical shape and has a diameter larger than the second inner through hole 23d and the second inner wall inner second through hole 48d between the other axial side of the low speed rotor 20 and the second inner wall 45c. It is arranged on the inner side of the direction and provided coaxially with the stator 10 .

A seventh baffle 46i is fixed to the high speed rotor 30 or the first end plate 22a. The eighth baffle 46j is fixed to the high speed rotor 30 or the second end plate 22b. The ninth baffle 46k is fixed to the low speed rotor 20 or the first inner wall 45b. The tenth baffle 46l is fixed to the low speed rotor 20 or the second inner wall 45c.

In FIG. 14, a first one-side heat exchanger 44c is arranged on one side in the axial direction of the first one-side fan 43c, and a second one-side heat exchanger is arranged on one side in the axial direction of the second one-side fan 43d. 44d is arranged, the first other side heat exchanger 44e is arranged on the other side in the axial direction of the first other side fan 43e, and the second other side heat exchanger 44e is arranged on the other side in the axial direction of the second other side fan 43f. A heat exchanger 44f is arranged. These arrangements are not limited to this, and as shown in FIG. 15, the arrangement of the fan 43 and the heat exchanger 44 may be reversed in the axial direction.

As described above, in the rotary electric machine 100 according to Embodiment 4, the third cooling passage 75 communicating with the third through-hole 33a and the fourth through-hole 33b is formed inside the high-speed rotor 30, and the high-speed rotor 30 has a high-speed rotor ventilation passage 34 radially penetrating between the first cooling passage 71 and the third cooling passage 75 at the axial center of the second body portion 35, and the four fans 43 Because the flow paths flowing in the opposite direction are formed in the first cooling flow path 71, the second cooling flow path 72, the third cooling flow path 75, the stator magnet cooling flow path 15, and the stator core cooling flow path 14 by , the flow path of the cooling gas formed by one fan 43 can be shortened, so the amount of boost required for one fan 43 can be reduced. Since the amount of boost required for one fan 43 can be reduced, it is possible to efficiently suppress variations in temperature distribution and temperature rise occurring in the low-speed rotor 20, the high-speed rotor 30, and the stator 10. FIG. Since the increase in temperature distribution variation and temperature rise occurring in the low-speed rotor 20, the high-speed rotor 30, and the stator 10 is suppressed, the temperature rise during operation of the rotating electrical machine 100 is suppressed, so that the output of the rotating electrical machine 100 is suppressed. can be increased.

When the rotating electrical machine 100 includes the seventh baffle 46i, the eighth baffle 46j, the ninth baffle 46k, and the tenth baffle 46l, it is possible to suppress the flow of the cooling gas in the radial direction. Cooling gas can be efficiently flowed to 75 .

Embodiment 5.
A rotating electric machine 100 according to Embodiment 5 will be described. FIG. 16 is a schematic diagram showing a cross section of the rotating electric machine 100 according to Embodiment 5, and is a diagram cut at a position equivalent to the AA cross section position in FIG. 1, and FIG. 18 is a schematic diagram showing the portion of the low-speed rotor 20 of the rotating electrical machine 100, showing the first end plate 22a side, and FIG. FIG. 20 is a schematic diagram showing a portion of the rotor 20, showing the side of the first end plate 22a; FIG. 21 is a schematic diagram showing a main part of another housing 45 of the rotating electrical machine 100, showing a first inner wall 45b; FIG. 22 is a schematic diagram showing a cross section of another rotating electrical machine 100 according to Embodiment 5; FIG. 17 is a view cut at the same position as in FIG. 16; A rotary electric machine 100 according to Embodiment 5 has a configuration in which a high-speed rotor 30 has a plurality of flow paths inside.

The third end plate 32a has a third through-hole 33a, a third inner through-hole 33c, and a third inner second through-hole 33e which penetrate in the axial direction in order from the radial outer side to the inner side. The fourth end plate 32b has a fourth through-hole 33b, a fourth inner through-hole 33d, and a fourth inner second through-hole 33f which are axially penetrated in order from the radially outer side to the inner side. Inside the high-speed rotor 30, there are a third cooling channel 75 communicating with the third through-hole 33a and the fourth through-hole 33b, and a fourth cooling channel communicating with the third inner through-hole 33c and the fourth inner through-hole 33d. 76, the third inner second through hole 33e, and the fourth inner second through hole 33f. The third cooling channel 75 , the fourth cooling channel 76 and the fifth cooling channel 77 are partitioned inside the high speed rotor 30 .

The first end plate 22a communicates with the third through hole 33a at a radial position radially inner than the first through hole 23a, and is axially penetrated through the first inner through hole 23c and through the first inner through hole 23c. a first inner second through-hole 23e that communicates with the third inner through-hole 33c at a radially inner position radially inward of the first inner second through-hole 23e, and a radially inner second through-hole 23e It has a first inner third through-hole 23g that communicates with the third inner second through-hole 33e at a position and penetrates in the axial direction. The second end plate 22b communicates with the fourth through-hole 33b at a radial position radially inner than the second through-hole 23b, and is axially penetrated through the second inner through-hole 23d and through the second inner through-hole 23d. a second inner second through-hole 23f that communicates with the fourth inner through-hole 33d at a radial position radially inner than the second inner through-hole 23d and extends radially inward from the second inner second through-hole 23f; It communicates with the fourth inner second through-hole 33f at a position and has a second inner third through-hole 23h that penetrates in the axial direction.

The first inner wall 45b communicates with the fourth cooling channel 76, and has a first inner wall inner third through hole 47e axially penetrating at a radial position radially inner than the first inner wall inner second through hole 47d, and a first inner wall inner fourth through hole 47f communicating with the fifth cooling flow path 77 and extending axially through the first inner wall inner third through hole 47e at a radial position radially inner than the first inner wall inner third through hole 47e. The second inner wall 45c communicates with the fourth cooling flow path 76 and has a second inner wall inner third through hole 48e axially penetrating at a radial position radially inner than the second inner wall inner second through hole 48d. and a second inner wall inner fourth through-hole 48f that communicates with the fifth cooling flow path 77 and penetrates in the axial direction at a radial position radially inner than the second inner wall inner third through-hole 48e.

Between the first inner wall 45b and the first outer wall 45d, a one-side first wall inner flow path 83a for cooling gas communicated with the first inner wall inner fourth through hole 47f and a cooling device communicated with the first inner wall inner through hole One side second wall inner channel 83b, one side first wall inner channel 83a, one side second wall inner channel 83b, first inner wall inner second through hole 47d and first inner wall inner third through hole 47d for gas A cooling gas flow path 83c in communication with the hole 47e is formed. Between the first inner wall 45b and the first outer wall 45d, a one-side fourth wall inner flow path 83d for communicating between the first inner wall outer through hole 47b and the first inner wall outer second through hole 47c is provided. It is formed. A cooling gas communicating between the second inner wall outer side second through hole 48c and the second inner wall inner side through hole 48a and the second inner wall inner side fourth through hole 48f between the second inner wall 45c and the second outer wall 45e. is formed between the second inner wall 45c and the second outer wall 45e, and between the second inner wall 45c and the second outer wall 45e, the second inner wall inner third through hole 48e, the second inner wall inner second through hole 48d and the second A cooling gas passage 84b in communication with the two inner wall outer through-holes 48b is formed.

A first one-side fan 43g, which is the fan 43, and a first one-side heat exchanger 44g, which is the heat exchanger 44, are arranged in the one-side third wall inner flow path 83c. A second one-side fan 43h, which is the fan 43, and a second one-side heat exchanger 44h, which is the heat exchanger 44, are arranged in the one-side fourth wall inner flow path 83d. In this embodiment, the fan 43 and the heat exchanger 44 are arranged only on one axial side of the rotating electric machine 100, and the fan 43 and the heat exchanger 44 are concentrated on the side opposite to the turbine blades 41. Therefore, the rotating electric machine The axial size of 100 can be reduced.

The first one-side fan 43g sends out the cooling gas toward the first inner wall inner second through-hole 47d and the first inner wall third through-hole 47e, and the second one-side fan 43h blows out the first inner wall outer side. The cooling gas is sent out toward the through hole 47b. Arrows 51 and 52 shown in FIG. 16 indicate the flow of cooling gas in this case. The flow of cooling gas is not limited to this. Along with sending out the gas, the second one-side fan 43h may also send out the cooling gas toward the side opposite to the side of the first inner wall outer through-hole 47b. In this case, the cooling gas flows in the opposite direction to the arrows shown in FIG.

In the portion surrounded by the dashed line in FIG. 16, the other-side first-wall inner channel 84a and the other-side second-wall inner channel 84b are provided to intersect. It is desirable that the intersecting channel portions are provided separately as shown in FIG. For example, the other-side first-wall inner channel 84a is provided as a tubular channel pipe, and the cooling gas flowing through the other-side first-wall inner channel 84a flows inside the pipe. The other side second wall inner channel 84b is formed outside the tube. By configuring in this way, it is possible to suppress mixing of cooling gases having different temperatures.

The flow of cooling gas will be described with reference to FIG. Three flow paths are formed from the cooling gas sent out from the first one-side fan 43g. One is the third cooling channel 75, the high-speed rotor ventilation channel 34, the first cooling channel 71, the one-side second-wall inner channel 83b, and the one-side third-wall inner channel 83c in this order. The other is the fourth cooling channel 76, the other side second wall inner channel 84b, the third cooling channel 75, the high speed rotor ventilation channel 34, the first cooling channel 71, the other side first wall inner flow It flows through the passage 84a, the fifth cooling passage 77, the one-side first-wall inner passage 83a, and the one-side third-wall inner passage 83c in this order. The other is the fourth cooling channel 76, the second inner wall channel 84b on the other side, the second cooling channel 72 and the stator magnet cooling channel 15, the stator ventilation channel 16 and the stator magnet ventilation channel 16a, The stator core cooling channel 14, the other side first wall inner channel 84a, the fifth cooling channel 77, the one side first wall inner channel 83a, and the one side third wall inner channel 83c flow in this order. The cooling gas sent out from the second one-side fan 43h passes through the second cooling passage 72, the stator magnet cooling passage 15, the stator air passage 16 and the stator magnet air passage 16a, the stator core cooling passage 14 , the one-side fourth wall inner channel 83d. The cooling gas passes through the first one-side heat exchanger 44g in the one-side third-wall inner channel 83c, and passes through the second one-side heat exchanger 44h in the one-side fourth-wall inner channel 83d.

In the first cooling channel 71 and the stator core cooling channel 14, and the second cooling channel 72, the stator magnet cooling channel 15 and the third cooling channel 75, at the same position in the axial direction, the cooling gas The axial direction of flow is different. Further, the fourth cooling channel 76 and the fifth cooling channel 77 have different axial directions in which the cooling gas flows at the same position in the axial direction.

By configuring in this way, the cooling gas flow path formed by one fan 43 can be shortened compared to the first and second embodiments. The main pressure loss that occurs in the cooling gas flow path inside rotating electric machine 100 is friction loss when the cooling gas passes through first cooling flow path 71 or second cooling flow path 72 having a small cross-sectional area. Since the passage of the cooling gas is shortened, the amount of boost required for one fan 43 can be reduced. In addition, since the cooling gas also flows through the third cooling channel 75, the fourth cooling channel 76, and the fifth cooling channel 77 formed in the high-speed rotor 30, the high-speed rotor 30 is cooled more efficiently. be able to.

Since FIG. 16 is a cross-sectional view, the first through hole 23a, the first inner through hole 23c, the first inner second through hole 23e, the first inner third through hole 23g, and the second end of the first end plate 22a. Although only one second through-hole 23b, second inner through-hole 23d, second inner second through-hole 23f, and second inner third through-hole 23h of the plate 22b are shown, the number of these through-holes is It is not limited to one. As shown in FIG. 18, a plurality of through holes may be provided at intervals. Moreover, the shape of each of these through holes is not limited to a circular shape, and may be a shape in which a plurality of through holes are connected along the outer periphery of the first end plate 22a as shown in FIG. Although only the example of the first end plate 22a is shown, the same applies to the through holes of the second end plate 22b.

Since FIG. 16 is a cross-sectional view, the first inner wall inner through hole 47a of the first inner wall 45b, the first inner wall outer through hole 47b, the first inner wall outer second through hole 47c, the first inner wall inner second through hole 47d, First inner wall inner third through-hole 47e, first inner wall inner fourth through-hole 47f, second inner wall inner through-hole 48a of second inner wall 45c, second inner wall outer through-hole 48b, second inner wall outer second through-hole 48c, the second inner wall inner second through-hole 48d, the second inner wall inner third through-hole 48e, and the second inner wall inner fourth through-hole 48f are each shown one, but the number of these through-holes is one. is not limited to As shown in FIG. 20, a plurality of through holes may be provided at intervals. Moreover, the shape of each of these through holes is not limited to a circle, and as shown in FIG. 21, a shape in which a plurality of through holes are connected along the outer periphery of the first inner wall 45b may be used. Although only an example of the first inner wall 45b is shown, the same applies to the through holes of the second inner wall 45c.

A baffle may be added to the rotary electric machine 100 . The seventh baffle 46i is formed in a cylindrical shape, and is radially inward of the third through hole 33a and the first inner through hole 23c between the one axial side of the high-speed rotor 30 and the first end plate 22a. Moreover, it is arranged radially outside the third inner through-hole 33c and the first inner second through-hole 23e and is provided coaxially with the stator 10 . The eighth baffle 46j is formed in a cylindrical shape, and is located between the other axial side of the high-speed rotor 30 and the second end plate 22b, radially inside the fourth through hole 33b and the second inner through hole 23d. Moreover, it is arranged radially outside the fourth inner through-hole 33d and the second inner second through-hole 23f and is provided coaxially with the stator 10 . A seventh baffle 46i is fixed to the high speed rotor 30 or the first end plate 22a. The eighth baffle 46j is fixed to the high speed rotor 30 or the second end plate 22b.

The ninth baffle 46k is formed in a cylindrical shape, and has a larger diameter than the first inner through hole 23c and the first inner wall inner second through hole 47d between the one axial side of the low speed rotor 20 and the first inner wall 45b. It is arranged radially inside the first inner side second through hole 23e and the first inner wall inner side third through hole 47e and provided coaxially with the stator 10 . The tenth baffle 46l is formed in a cylindrical shape and has a diameter larger than the second inner through hole 23d and the second inner wall inner second through hole 48d between the other axial side of the low speed rotor 20 and the second inner wall 45c. It is arranged radially inward of the second inner second through hole 23f and the second inner wall inner third through hole 48e and provided coaxially with the stator 10 . The ninth baffle 46k is fixed to the low speed rotor 20 or the first inner wall 45b. The tenth baffle 46l is fixed to the low speed rotor 20 or the second inner wall 45c.

The eleventh baffle 46m is formed in a cylindrical shape, and between the one axial side of the high-speed rotor 30 and the first end plate 22a, more than the third inner through hole 33c and the first inner second through hole 23e. It is arranged radially inward and radially outward of the third inner second through hole 33e and the first inner third through hole 23g, and is provided coaxially with the stator 10 . The twelfth baffle 46n is formed in a cylindrical shape, and between the other axial side of the high-speed rotor 30 and the second end plate 22b, more than the fourth inner through hole 33d and the second inner second through hole 23f. It is arranged radially inward and radially outward of the fourth inner second through hole 33f and the second inner third through hole 23h, and is provided coaxially with the stator 10 . The eleventh baffle 46m is fixed to the high speed rotor 30 or the first end plate 22a. A twelfth baffle 46n is fixed to the high speed rotor 30 or the second end plate 22b.

The thirteenth baffle 46o is formed in a cylindrical shape, and between the one axial side of the low-speed rotor 20 and the first inner wall 45b, a first inner second through hole 23e and a first inner wall inner third through hole 47e are provided. and radially outside the first inner third through-hole 23g and the first inner wall inner fourth through-hole 47f. The fourteenth baffle 46p is formed in a cylindrical shape, and between the other axial side of the low-speed rotor 20 and the second inner wall 45c, a second inner second through hole 23f and a second inner wall inner third through hole 48e are provided. and radially outside the second inner third through-hole 23h and the second inner wall inner fourth through-hole 48f, and provided coaxially with the stator 10 . The thirteenth baffle 46o is fixed to the low speed rotor 20 or the first inner wall 45b. The fourteenth baffle 46p is fixed to the low speed rotor 20 or the second inner wall 45c.

In FIG. 16, a first one-side heat exchanger 44g is arranged on one side in the axial direction of the first one-side fan 43g, and a second one-side heat exchanger is arranged on one side in the axial direction of the second one-side fan 43h. A container 44h is arranged. These arrangements are not limited to this, and as shown in FIG. 22, the arrangement of the fan 43 and the heat exchanger 44 may be reversed in the axial direction.

As described above, in the rotating electrical machine 100 according to Embodiment 5, the third cooling channel 75, the fourth cooling channel 76, and the fifth cooling channel 77 are formed inside the high-speed rotor 30, and the high-speed rotor 30 has a high-speed rotor ventilation passage 34 radially penetrating between the first cooling passage 71 and the third cooling passage 75 at the axial center of the second body portion 35, and two fans 43 form a flow path flowing in the opposite direction through the first cooling flow path 71, the second cooling flow path 72, the third cooling flow path 75, the stator magnet cooling flow path 15, and the stator core cooling flow path 14. Therefore, the flow path of the cooling gas formed by one fan 43 can be shortened, so that the amount of boost required for one fan 43 can be reduced. Since the amount of boost required for one fan 43 can be reduced, it is possible to efficiently suppress variations in temperature distribution and temperature rise occurring in the low-speed rotor 20, the high-speed rotor 30, and the stator 10. FIG. Since the increase in temperature distribution variation and temperature rise occurring in the low-speed rotor 20, the high-speed rotor 30, and the stator 10 is suppressed, the temperature rise during operation of the rotating electrical machine 100 is suppressed, so that the output of the rotating electrical machine 100 is suppressed. can be increased.

The fan 43 and the heat exchanger 44 are arranged only on one axial side of the rotating electrical machine 100 , and the fan 43 and the heat exchanger 44 are concentrated on the side opposite to the turbine blades 41 , so that the axial size of the rotating electrical machine 100 is reduced. can be made smaller. Further, when the rotary electric machine 100 includes the eleventh baffle 46m, the twelfth baffle 46n, the thirteenth baffle 46o, and the fourteenth baffle 46p, it is possible to suppress the radial flow of the cooling gas. The cooling gas can efficiently flow through the fourth cooling channel 76 and the fifth cooling channel 77 .

Also, while this application has described various exemplary embodiments and examples, various features, aspects, and functions described in one or more of the embodiments may vary from particular embodiment to specific embodiment. The embodiments are applicable singly or in various combinations without being limited to the application.
Accordingly, numerous variations not illustrated are envisioned within the scope of the technology disclosed herein. For example, modification, addition or omission of at least one component, extraction of at least one component, and combination with components of other embodiments shall be included.

Reference Signs List 10 stator 11 stator coil 12 stator magnet 13 stator core 13a stator slot 13b stator tooth 14 stator core cooling channel 15 stator magnet cooling channel 16 stator ventilation channel , 16a stator magnet air passage, 20 low speed rotor, 21 pole piece, 22a first end plate, 22b second end plate, 23a first through hole, 23b second through hole, 23c first inner through hole, 23d second Two inner through holes 23e First inner second through hole 23f Second inner second through hole 23g First inner third through hole 23h Second inner third through hole 24 Low-speed rotor air passage 25 Insulation material, 26 first main body, 30 high-speed rotor, 31 high-speed rotor magnet, 32a third end plate, 32b fourth end plate, 33a third through hole, 33b fourth through hole, 33c third inner through hole, 33d fourth inner through-hole 33e third inner second through-hole 33f fourth inner second through-hole 34 high-speed rotor air passage 35 second main body 40 rotating shaft 41 turbine blade 42 bearing 43 Fan 44 Heat exchanger 45 Housing 45a Surrounding wall 45b First inner wall 45c Second inner wall 45d First outer wall 45e Second outer wall 46a First baffle 46b Second baffle 46c Third baffle 46d 4th baffle, 46e 5th baffle, 46f 6th baffle, 46g 1st stator baffle, 46h 2nd stator baffle, 46i 7th baffle, 46j 8th baffle, 46k 9th baffle, 46l 10th baffle, 46m Eleventh baffle 46n Twelfth baffle 46o Thirteenth baffle 46p Fourteenth baffle 47a First inner wall inner through hole 47b First inner wall outer through hole 47c First inner wall outer second through hole 47d One inner wall inner second through hole 47e First inner wall inner third through hole 47f First inner wall inner fourth through hole 48a Second inner wall inner through hole 48b Second inner wall outer through hole 48c Second inner wall outer third through hole Two through holes 48d Second inner wall inner second through hole 48e Second inner wall inner third through hole 48f Second inner wall inner fourth through hole 51 Arrow 52 Arrow 61 First gap 62 Second gap 71 first cooling channel 72 second cooling channel 73 one side wall inner channel 74 other side wall inner channel 75 third cooling channel 76 fourth cooling channel 77 fifth cooling channel 80a One side first wall inner channel 80b One side second wall inner channel 80c One side third wall inner channel 81a Other side first wall inner channel 81b Other side second wall inner channel 81c Other side third wall inner channel 82a First one side wall inner channel 82b Second one side wall inner channel 82c First other side wall inner channel 82d Second other side wall inner channel 83a One side first wall inner channel 83b One side second wall inner channel 83c One side third wall inner channel 83d One side fourth wall inner channel 84a Other side first wall inner channel 84b Other side second wall inner flow path, 100 Rotating electric machine

Claims (15)

a rotating shaft;
A stator core in which a plurality of stator slots that open radially inward are provided in a circumferential direction, stator coils that are arranged on the bottom side of each of the plurality of stator slots, and openings of the plurality of stator slots. and a stator magnet cooling passage provided between the stator coil and the stator magnet and penetrating in the axial direction. and a stator
It has a cylindrical first body portion and a plurality of magnetic pole pieces provided on the first body portion at intervals in the circumferential direction, and is provided coaxially with the stator facing the stator magnets. , a first rotor that rotates integrally with the rotating shaft;
It has a cylindrical second main body and a plurality of permanent magnets arranged at intervals in the circumferential direction on the outer peripheral part of the second main body, and faces the radially inner wall surface of the first main body. and a second rotor provided coaxially with the first rotor;
a peripheral wall surrounding the stator from the outside in the radial direction; a first inner wall connected to the peripheral wall and covering one axial side of the stator, the first rotor, and the second rotor; , a second inner wall that covers the other axial side of the stator, the first rotor, and the second rotor, and is connected to the peripheral wall and covers the one axial side of the first inner wall with a gap therebetween. a housing having a first outer wall and a second outer wall connected to the peripheral wall and covering the other side of the second inner wall in the axial direction with a space therebetween;
a fan disposed inside the housing for sending cooling gas;
a heat exchanger arranged inside the housing and through which the cooling gas passes;
The first main body portion extends radially inward from an end portion on one axial side between the second rotor and the first inner wall in the axial direction, and is fixed to the rotating shaft. an end plate, and a second end plate that extends radially inward from the other end in the axial direction between the second rotor and the second inner wall in the axial direction and is fixed to the rotating shaft; have
The first end plate has a first through hole axially penetrating in a radially outer portion,
The second end plate has a second through hole axially penetrating in a radially outer portion,
A first cooling channel communicating with the first through hole and the second through hole is formed between the first body portion and the second rotor,
A second cooling channel is formed between the first main body and the stator,
The first inner wall communicates with the first cooling passage and communicates with the first inner wall inner through-hole extending axially therethrough, the second cooling passage and the stator magnet cooling passage, and communicates with the first cooling passage. having a first inner wall outer through hole axially penetrating at a radial position radially outer than the inner wall inner through hole,
The second inner wall communicates with the first cooling passage and communicates with the second inner wall inner through-hole extending axially therethrough, the second cooling passage and the stator magnet cooling passage, and communicates with the second cooling passage. having a second inner wall outer through hole axially penetrating at a radial position radially outer than the inner wall inner through hole,
the fan is positioned between one or both of the first inner wall and the first outer wall and between the second inner wall and the second outer wall;
the heat exchanger is positioned between one or both of the first inner wall and the first outer wall and between the second inner wall and the second outer wall;
The rotary electric machine, wherein the first cooling passage, the second cooling passage, and the stator magnet cooling passage have different axial directions in which the cooling gas flows at the same position in the axial direction. formed in a cylindrical shape, disposed radially inward of the first through-hole between one axial side of the second rotor and the first end plate, and provided coaxially with the stator. and a first baffle formed in a cylindrical shape, disposed radially inward of the second through hole between the other axial side of the second rotor and the second end plate, and the fixing A second baffle provided coaxially with the child,
the first baffle is fixed to the second rotor or the first end plate;
The rotating electric machine according to claim 1, wherein said second baffle is fixed to said second rotor or said second end plate. formed in a cylindrical shape and arranged radially inward of the first inner wall inner through-hole and the first through-hole between one axial side of the first end plate and the first inner wall; A third baffle provided coaxially with the child, and a cylindrically formed second inner wall inner through-hole and the second through-hole between the other side of the second end plate in the axial direction and the second inner wall A fourth baffle disposed radially inward of the hole and provided coaxially with the stator,
The third baffle is fixed to the first end plate or the first inner wall,
The rotating electric machine according to claim 1 or 2, wherein the fourth baffle is fixed to the second end plate or the second inner wall. formed in a cylindrical shape, and between the axial one-side end surface of the first rotor and the first inner wall, radially inner than the first inner wall outer through-hole, and the first through-hole and the a fifth baffle arranged radially outside the first inner wall inner through-hole and provided coaxially with the stator; between the second inner wall and radially inside the second inner wall outer through-hole and radially outer than the second through-hole and the second inner wall inner through-hole, coaxially with the stator provided with a sixth baffle,
The fifth baffle is fixed to the first end plate or the first inner wall,
The rotating electric machine according to any one of claims 1 to 3, wherein the sixth baffle is fixed to the second end plate or the second inner wall. Between the first inner wall and the first outer wall, a one side wall inner flow path is formed for communication between the first inner wall outer through-hole and the first inner wall inner through-hole, and
The fan is arranged inside the one side wall inner channel and sends out a cooling gas,
Between the second inner wall and the second outer wall, a flow path in the other side wall of the cooling gas communicating between the second inner wall outer through-hole and the second inner wall inner through-hole is formed,
The rotating electric machine according to any one of claims 1 to 4, wherein the heat exchanger is arranged inside the second side wall inner flow path. Between the first inner wall and the first outer wall, a one side wall inner flow path is formed for communication between the first inner wall outer through-hole and the first inner wall inner through-hole, and
The fan is arranged inside the one side wall inner channel and sends out a cooling gas,
The heat exchanger is disposed inside the one side wall inner flow path, and is disposed between the second inner wall and the second outer wall, and between the second inner wall outer through hole and the second inner wall inner through hole. 5. The electric rotating machine according to any one of claims 1 to 4, wherein a communicating cooling gas flow path is formed in the other side wall. The stator core has a stator core cooling channel provided radially outside the stator coil and penetrating in the axial direction,
The first inner wall has a first inner wall outer second through hole that communicates with the stator core cooling flow path and penetrates in the axial direction at a radial position radially outer than the first inner wall outer through hole. ,
The second inner wall has a second inner wall outer second through hole that communicates with the stator core cooling flow path and penetrates in the axial direction at a radial position radially outer than the second inner wall outer through hole. ,
One of the cooling gas communicating between the first inner wall outer through-hole and the first inner wall outer second through-hole and the first inner wall inner through-hole between the first inner wall and the first outer wall A channel inside the side wall is formed,
The fan is arranged inside the one side wall inner channel and sends out a cooling gas,
The other of the cooling gas communicating between the second inner wall outer through-hole and the second inner wall outer second through-hole and the second inner wall inner through-hole between the second inner wall and the second outer wall A channel inside the side wall is formed,
The heat exchanger is arranged inside the second side wall inner flow path,
In the first cooling passage, the second cooling passage, the stator magnet cooling passage, and the stator core cooling passage, at the same position in the axial direction, the axial direction of the cooling gas flow is The rotating electric machine according to any one of claims 1 to 4, which are different. The stator core has a stator core cooling channel provided radially outside the stator coil and penetrating in the axial direction,
The first inner wall has a first inner wall outer second through hole that communicates with the stator core cooling flow path and penetrates in the axial direction at a radial position radially outer than the first inner wall outer through hole. ,
The second inner wall has a second inner wall outer second through hole that communicates with the stator core cooling flow path and penetrates in the axial direction at a radial position radially outer than the second inner wall outer through hole. ,
One of the cooling gas communicating between the first inner wall outer through-hole and the first inner wall outer second through-hole and the first inner wall inner through-hole between the first inner wall and the first outer wall A channel inside the side wall is formed,
The fan is arranged inside the one side wall inner channel and sends out a cooling gas,
The heat exchanger is arranged inside the one side wall inner channel,
The other of the cooling gas communicating between the second inner wall outer through-hole and the second inner wall outer second through-hole and the second inner wall inner through-hole between the second inner wall and the second outer wall A channel inside the side wall is formed,
In the first cooling passage, the second cooling passage, the stator magnet cooling passage, and the stator core cooling passage, at the same position in the axial direction, the axial direction of the cooling gas flow is The rotating electric machine according to any one of claims 1 to 4, which are different. The stator core includes a stator core cooling passage that is provided radially outward of the stator coil and penetrates in the axial direction, and the second cooling passage at the axial center of the stator core. a stator ventilation passage penetrating radially between the stator core cooling passage and communicating the second cooling passage, the stator core cooling passage, and the stator magnet cooling passage; ,
The first main body radially penetrates between the first cooling flow path and the second cooling flow path at an axial central portion of the first main body, having a first rotor ventilation passage communicating with the second cooling passage;
The first inner wall has a first inner wall outer second through hole that communicates with the stator core cooling flow path and penetrates in the axial direction at a radial position radially outer than the first inner wall outer through hole. ,
The second inner wall has a second inner wall outer second through hole that communicates with the stator core cooling flow path and penetrates in the axial direction at a radial position radially outer than the second inner wall outer through hole. ,
Between the first inner wall and the first outer wall, a one-side first-wall inner channel communicating with the first inner-wall inner through-hole and a one-side second inner-wall channel communicating with the first inner-wall outer second through-hole an in-wall channel and a one-side third-wall in-wall channel communicating between the one-side first wall channel and the one-side second wall channel and the first inner wall outer through-hole are formed;
Between the second inner wall and the second outer wall, the other side first wall inner flow path communicating with the second inner wall inner through hole, and the other side second wall communicating with the second inner wall outer second through hole an in-wall channel and a second-side third-wall channel in communication with the other-side first-wall channel, the other-side second-wall channel, and the second inner-wall-outer through-hole are formed;
The first fan that is the fan and the first heat exchanger that is the heat exchanger are arranged in the one-side third wall inner flow path,
A second fan that is the fan and a second heat exchanger that is the heat exchanger are arranged in the other side third wall inner flow path,
The first fan sends cooling gas toward the first inner-wall-outer through-hole side, and the second fan sends out cooling gas toward the second inner-wall-outer through-hole side, or One fan sends cooling gas toward the side opposite to the first inner wall outer through-hole side, and the second fan sends cooling gas toward the side opposite to the second inner wall outer through-hole side. send out,
In the first cooling passage and the stator core cooling passage and the second cooling passage and the stator magnet cooling passage, the cooling gas flows in different axial directions at the same position in the axial direction. The rotary electric machine according to any one of claims 1 to 4. The stator magnet radially penetrates between the second cooling flow path and the stator magnet cooling flow path at a center portion in the axial direction of the stator magnet, Having a stator magnet ventilation passage communicating with the stator magnet cooling passage,
The rotating electric machine according to claim 9, wherein the stator magnet air passage communicates with the first rotor air passage. Between the one axial side of the stator core and the first inner wall, radially inner than the stator core cooling passage and the first inner wall outer second through hole, and the first inner wall outer through hole A first stator baffle disposed radially outward from the stator and provided coaxially with the stator, and between the other axial side of the stator core and the second inner wall, the stator core cooling flow a second stator baffle disposed radially inward of the passage and the second inner wall outer side second through hole and radially outer than the second inner wall outer side through hole and provided coaxially with the stator; ,
the first stator baffle is secured to the stator or the first inner wall or both;
The rotating electric machine according to any one of claims 7 to 10, wherein the second stator baffle is fixed to the stator, the second inner wall, or both. The second main body extends radially inward from one end in the axial direction, and includes a third end plate connected to the rotating shaft via a bearing, and a radial extension from the other end in the axial direction. having a fourth end plate extending inward in the direction and connected to the rotating shaft via a bearing;
The third end plate has a third through-hole that penetrates in the axial direction,
The fourth end plate has a fourth through-hole that penetrates in the axial direction,
a third cooling flow path communicating with the third through-hole and the fourth through-hole is formed inside the second rotor;
The second rotor radially penetrates between the first cooling flow path and the third cooling flow path at the axial center of the second main body, and the first cooling flow path and a second rotor ventilation passage that communicates with the third cooling passage,
the first end plate has a first inner through-hole communicating with the third through-hole at a radially inner position radially inward of the first through-hole and passing through in the axial direction;
the second end plate has a second inner through-hole communicating with the fourth through-hole at a radially inner position radially inward of the second through-hole and passing through in the axial direction;
The stator core includes a stator core cooling passage provided radially outward of the stator coil and penetrating in the axial direction, and the stator magnet cooling passage at the axial center of the stator core. and the stator core cooling channel radially penetrating therethrough and communicating the stator magnet cooling channel and the stator core cooling channel,
The stator magnet radially penetrates between the second cooling flow path and the stator magnet cooling flow path at a center portion in the axial direction of the stator magnet, having a stator magnet cooling passage communicating with the stator ventilation passage;
The first inner wall has a first inner wall outer second through hole that communicates with the stator core cooling flow path and penetrates in the axial direction at a radial position radially outer than the first inner wall outer through hole, and Having a first inner wall inner second through hole that communicates with the third cooling flow path and axially penetrates at a radial position radially inner than the first inner wall inner through hole,
The second inner wall has a second inner wall outer second through hole that communicates with the stator core cooling flow path and penetrates in the axial direction at a radial position radially outer than the second inner wall outer through hole, and a second inner wall inner second through hole that communicates with the third cooling flow path and extends axially through the second inner wall inner through hole at a radial position that is radially inner than the second inner wall inner through hole;
Between the first inner wall and the first outer wall, there is formed a first one side wall inner flow path for communicating between the first inner wall inner through-hole and the first inner wall inner second through-hole. is,
Between the first inner wall and the first outer wall, a second one side wall inner flow path for communicating between the first inner wall outer through hole and the first inner wall outer second through hole is formed. is,
A first other side wall inner flow path communicating between the second inner wall inner through hole and the second inner wall inner second through hole is formed between the second inner wall and the second outer wall,
A second other side wall inner flow path is formed between the second inner wall and the second outer wall to communicate between the second inner wall outer through hole and the second inner wall outer second through hole,
The first one-side fan that is the fan and the first one-side heat exchanger that is the heat exchanger are arranged in the first one-side wall inner flow path,
A second one-side fan that is the fan and a second one-side heat exchanger that is the heat exchanger are arranged in the second one-side wall inner flow path,
The first other side fan that is the fan and the first other side heat exchanger that is the heat exchanger are arranged in the first other side wall inner flow path,
The second other side fan that is the fan and the second other side heat exchanger that is the heat exchanger are arranged in the second other side wall inner flow path,
The first one-side fan sends out cooling gas toward the first inner wall inner second through-hole side, and the second one-side fan directs the first inner wall outer through-hole side to the first inner wall through-hole side. One of the other-side fans sends cooling gas toward the second inner wall inner side of the second through-hole, and the second other-side fan of the second side fan sends cooling gas toward the second inner wall outer side of the through-hole, or the second One one-side fan sends out cooling gas toward the side opposite to the second through-hole side inside the first inner wall, and the second one-side fan is directed to the side opposite to the first inner-wall outside through-hole side. , the first other side fan is directed to the side opposite to the second inner wall inner second through hole side, and the second other side fan is directed to the second inner wall outer side through hole side send cooling gas towards the other side,
In the first cooling passage and the stator core cooling passage, and in the second cooling passage, the stator magnet cooling passage and the third cooling passage, cooling gas The rotary electric machine according to any one of claims 1 to 4, wherein the axial directions of the flows are different. Between the one axial side of the stator core and the first inner wall, radially inner than the stator core cooling passage and the first inner wall outer second through hole, and the first inner wall outer through hole A first stator baffle disposed radially outside and coaxial with the stator, between the other axial side of the stator core and the second inner wall, the stator core cooling flow path and a second stator baffle arranged radially inside the second inner wall outside second through hole and radially outside the second inner wall outside through hole and provided coaxially with the stator, cylindrical and is arranged radially inward of the third through hole and the first inner through hole between the one axial side of the second rotor and the first end plate, and the stator A seventh baffle provided coaxially with the fourth through hole and the second inner through hole formed in a cylindrical shape between the other axial side of the second rotor and the second end plate An eighth baffle disposed radially inward of the stator and provided coaxially with the stator, formed in a cylindrical shape, between one axial side of the first rotor and the first inner wall, the A ninth baffle arranged radially inward of the first inner through hole and the first inner wall inner second through hole and provided coaxially with the stator, and a cylindrically formed first rotor between the other axial side of and the second inner wall, the second inner through hole and the second inner wall inner side second through hole arranged radially inward, and provided coaxially with the stator Equipped with ten baffles,
the first stator baffle is secured to the stator or the first inner wall or both;
the second stator baffle is secured to the stator or the second inner wall or both;
the seventh baffle is fixed to the second rotor or the first end plate;
the eighth baffle is fixed to the second rotor or the second end plate;
The ninth baffle is fixed to the first rotor or the first inner wall,
The rotating electric machine according to claim 12, wherein the tenth baffle is fixed to the first rotor or the second inner wall. The second main body extends radially inward from one end in the axial direction, and includes a third end plate connected to the rotating shaft via a bearing, and a radial extension from the other end in the axial direction. having a fourth end plate extending inward in the direction and connected to the rotating shaft via a bearing;
the third end plate has a third through-hole, a third inner through-hole, and a third inner second through-hole in order from the radially outer side to the inner side, and
the fourth end plate has a fourth through-hole, a fourth inner through-hole, and a fourth inner second through-hole in order from the radially outer side to the inner side;
Inside the second rotor, a third cooling flow path communicated with the third through hole and the fourth through hole, and a fourth cooling flow path communicated with the third inner through hole and the fourth inner through hole and a fifth cooling channel communicating with the third inner second through hole and the fourth inner second through hole,
The third cooling channel, the fourth cooling channel, and the fifth cooling channel are partitioned inside the second rotor,
The second rotor radially penetrates between the first cooling flow path and the third cooling flow path at the axial center of the second main body, and the first cooling flow path and a second rotor ventilation passage that communicates with the third cooling passage,
The first end plate communicates with the third through hole at a radial position radially inner than the first through hole, and extends axially through the first inner through hole, the first inner through hole. a first inner second through-hole that communicates with the third inner through-hole at a radially inner radial position and extends axially through the third inner through-hole; and a radial position radially inner than the first inner second through-hole Having a first inner third through hole communicating with the third inner second through hole and penetrating in the axial direction,
The second end plate communicates with the fourth through hole at a radial position radially inner than the second through hole, and extends through the second inner through hole in the axial direction. a second inner second through-hole that communicates with the fourth inner through-hole at a radially inner radial position and penetrates in the axial direction; and a radial position radially inner than the second inner second through-hole Having a second inner third through hole that communicates with the fourth inner second through hole and penetrates in the axial direction,
The stator core includes a stator core cooling passage provided radially outward of the stator coil and penetrating in the axial direction, and the stator magnet cooling passage at the axial center of the stator core. and the stator core cooling channel radially penetrating therethrough and communicating the stator magnet cooling channel and the stator core cooling channel,
The stator magnet radially penetrates between the second cooling flow path and the stator magnet cooling flow path at a center portion in the axial direction of the stator magnet, having a stator magnet cooling passage communicating with the stator ventilation passage;
The first inner wall communicates with the stator core cooling flow path and axially penetrates the first inner wall outer second through hole at a radial position radially outer than the first inner wall outer through hole; A first inner wall inner second through hole that communicates with three cooling channels and axially penetrates at a radial position radially inner than the first inner wall inner through hole, communicates with the fourth cooling channel, and The first inner wall inner third through hole communicates with the first inner wall inner third through hole axially penetrating at a radial position radially inner than the first inner wall inner second through hole and the fifth cooling passage, and the first inner wall inner third having a first inner wall inner fourth through hole axially penetrating at a radial position radially inner than the through hole,
The second inner wall communicates with the stator core cooling flow path and axially penetrates the second inner wall outer side second through hole at a radial position radially outer than the second inner wall outer side through hole; A second inner wall inner second through hole which communicates with the third cooling channel and axially penetrates at a radial position radially inner than the second inner wall inner through hole, communicates with the fourth cooling channel, and communicates with the The second inner wall inner third through-hole communicates with the second inner wall inner third through-hole axially penetrating at a radial position radially inner than the second inner wall inner second through-hole and the fifth cooling passage, and the second inner wall inner third through-hole having a second inner wall inner fourth through hole axially penetrating at a radial position radially inner than the hole,
Between the first inner wall and the first outer wall, a one-side first wall inner flow path for cooling gas communicating with the first inner wall inner fourth through hole, and a cooling medium communicating with the first inner wall inner through hole One side second wall inner channel for gas, said one side first wall inner channel, said one side second wall inner channel, said first inner wall inner second through hole, and said first inner wall inner third through hole a channel in the one-side third wall of the cooling gas communicating with the hole is formed,
Between the first inner wall and the first outer wall, a one-side fourth wall inner flow path is formed for communicating between the first inner wall outer through-hole and the first inner wall outer second through-hole. is,
Cooling gas communicating between the second inner wall outer side second through hole and the second inner wall inner side through hole, and the second inner wall inner side fourth through hole between the second inner wall and the second outer wall The other side of the first wall inner flow path is formed,
Cooling gas communicating between the second inner wall inner third through-hole, the second inner wall inner second through-hole and the second inner wall outer through-hole between the second inner wall and the second outer wall A channel in the second wall is formed on the other side of the
The first one-side fan that is the fan and the first one-side heat exchanger that is the heat exchanger are arranged in the one-side third wall inner flow path,
A second one-side fan that is the fan and a second one-side heat exchanger that is the heat exchanger are arranged in the one-side fourth wall inner flow path,
The first one-side fan sends cooling gas toward the second through-hole inside the first inner wall and the third through-hole inside the first inner wall, and the second one-side fan rotates outside the first inner wall. Cooling gas is sent toward the through hole side, or the first one-side fan directs toward the side opposite to the first inner wall inner second through hole and the first inner wall inner third through hole side While sending out the cooling gas, the second one-side fan sends out the cooling gas toward the side opposite to the side of the first inner wall outer through-hole, the first cooling passage and the stator core cooling passage; In the second cooling channel, the stator magnet cooling channel, and the third cooling channel, the cooling gas flows in different axial directions at the same position in the axial direction,
5. The electric rotating machine according to any one of claims 1 to 4, wherein the fourth cooling passage and the fifth cooling passage have different axial directions in which the cooling gas flows at the same position in the axial direction. . Between the one axial side of the stator core and the first inner wall, radially inner than the stator core cooling passage and the first inner wall outer second through hole, and the first inner wall outer through hole A first stator baffle disposed radially outside and coaxial with the stator, between the other axial side of the stator core and the second inner wall, the stator core cooling flow path and a second stator baffle arranged radially inside the second inner wall outside second through hole and radially outside the second inner wall outside through hole and provided coaxially with the stator, cylindrical between the axial one side of the second rotor and the first end plate, radially inner than the third through hole and the first inner through hole, and the third inner through hole A seventh baffle arranged radially outward of the hole and the first inner second through-hole and provided coaxially with the stator, is formed in a cylindrical shape, and is located on the other side of the second rotor in the axial direction. Between the second end plate, radially inner than the fourth through hole and the second inner through hole, and radially outer than the fourth inner through hole and the second inner second through hole An eighth baffle arranged coaxially with the stator, formed in a cylindrical shape, between the first inner wall and the first inner through-hole and radially inner than the first inner wall inner second through hole and radially outer than the first inner wall inner second through hole and the first inner wall inner third through hole, and provided coaxially with the stator a ninth baffle formed in a cylindrical shape, between the second inner through hole and the inner second through hole of the second inner wall between the other side of the first rotor in the axial direction and the second inner wall a tenth baffle disposed coaxially with the stator, radially inward and radially outward of the second inner second through hole and the second inner wall inner third through hole, formed in a cylindrical shape between the axial one side of the second rotor and the first end plate, radially inside the third inner through hole and the first inner second through hole, and the third inner side An eleventh baffle disposed radially outwardly of the second through hole and the first inner third through hole and provided coaxially with the stator, formed in a cylindrical shape, the axis of the second rotor between the other side of the direction and the second end plate, radially inner than the fourth inner through hole and the second inner second through hole, and the fourth inner second through hole and the second inner second through hole; A twelfth baffle arranged radially outward of the three through-holes and provided coaxially with the stator, formed in a cylindrical shape, between one axial side of the first rotor and the first inner wall between the first inner second through hole and the first inner wall inner third through hole, and radially inner than the first inner third through hole and the first inner wall inner fourth through hole a thirteenth baffle arranged outside and provided coaxially with the stator; arranged radially inward of the inner second through-hole and the second inner wall inner third through-hole and radially outer than the second inner third through-hole and the second inner wall inner fourth through-hole, A fourteenth baffle provided coaxially with the stator,
the first stator baffle is secured to the stator or the first inner wall or both;
the second stator baffle is secured to the stator or the second inner wall or both;
the seventh baffle is fixed to the second rotor or the first end plate;
the eighth baffle is fixed to the second rotor or the second end plate;
The ninth baffle is fixed to the first rotor or the first inner wall,
The tenth baffle is fixed to the first rotor or the second inner wall,
The eleventh baffle is fixed to the second rotor or the first end plate,
The twelfth baffle is fixed to the second rotor or the second end plate,
The thirteenth baffle is fixed to the first rotor or the first inner wall,
The rotating electric machine according to claim 14, wherein the fourteenth baffle is fixed to the first rotor or the second inner wall.

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