JP6650982B1 - Rotating electric machine and its cooling system - Google Patents

Abstract

To cool an entire rotating electric machine. A housing (60) of a rotating electric machine (10) is provided with a jacket (112) for flowing a coolant supplied from a coolant supply port (110). The jacket 112 discharges the refrigerant to the stator 68 through the discharge port 112b, and supplies the refrigerant to the refrigerant passage 120 of the rotor shaft 66 through the branch passage 112c. The two end plates 70L and 70R of the rotor 64 are formed with refrigerant passages 124L and 124R through which the refrigerant supplied from the refrigerant passage 120 flows. The refrigerant that drops from the first internal space 62 of the housing 60 is stored in the refrigerant storage unit 114. The pump 44 discharges the refrigerant stored in the refrigerant storage unit 114 to the outside. [Selection] Figure 2

Description

  The present invention relates to a rotating electric machine having a rotor, a rotor shaft coaxially connected to the rotor, and a stator, and a cooling system therefor.

  For example, Patent Document 1 discloses a cooling structure of a motor having a rotor, a rotor shaft coaxially connected to the rotor, and a stator. In this case, the refrigerant is supplied to the hollow rotor shaft, and the supplied refrigerant is circulated through the flux barrier of the rotor core. Thereby, the permanent magnet embedded in the rotor core is cooled. Further, a groove communicating with the flux barrier is formed in the end plate of the rotor in the radial direction, and the refrigerant is scattered from the flux barrier to the stator via the groove to cool the winding of the stator.

JP 2009-27800 A

  As described above, conventionally, the main focus has been on cooling the rotor and the stator, and the viewpoint of cooling the entire rotating electric machine has not been sufficiently considered.

  In addition, it is necessary to construct an optimal refrigerant path for cooling the inside of the rotating electric machine.

  The present invention has been made in consideration of such problems, and has as its object to provide a rotating electric machine that can cool the entire rotating electric machine and suppress the influence of heat received from the surroundings, and a cooling system thereof. And Another object of the present invention is to provide a rotating electric machine in which an optimal refrigerant path is constructed and a cooling system therefor.

  A first aspect of the present invention relates to a rotating electric machine having a rotor, a rotor shaft coaxially connected to the rotor, and a stator. In a first aspect, the rotating electric machine further includes a housing, a jacket, two end plates, a refrigerant storage unit, and a pump.

  The housing houses the rotor, the rotor shaft and the stator so as to cover the outer periphery of the stator, and includes a refrigerant supply port through which a refrigerant from the outside is supplied. The jacket is provided between the housing and the stator, a first refrigerant passage through which the refrigerant supplied from the refrigerant supply port flows, and a second refrigerant passage which discharges the refrigerant flowing through the first refrigerant passage to the stator. A first discharge port; and a branch passage that branches the refrigerant flowing through the first refrigerant passage and supplies the branched refrigerant to the rotor shaft. The rotor shaft includes a second refrigerant passage through which the refrigerant supplied from the branch passage flows. The two end plates are provided at both ends in the axial direction of the rotor, respectively, and include third refrigerant passages through which the refrigerant supplied from the second refrigerant passage flows. The refrigerant storage unit is provided at a bottom of the housing, and stores the refrigerant in the housing. The pump is driven in accordance with the rotation of the rotor to discharge the refrigerant stored in the refrigerant storage unit to the outside.

  A second aspect of the present invention relates to a rotating electric machine including a rotor, a rotor shaft coaxially connected to the rotor, a stator, and two end plates provided at both ends in the axial direction of the rotor.

  In a second aspect, the rotor shaft is provided in the axial direction inside the rotor shaft, and has an internal flow path through which a refrigerant supplied from the outside flows, and opens from the internal flow path in a radial direction of the rotor shaft. The refrigerant supplied from the internal flow path via the rotor shaft side discharge port to the end plate or the rotor. An external flow path. Further, the two end plates are respectively provided with a plurality of end plate-side refrigerant passages formed radially from the rotor shaft as viewed from the axial direction, and end ends provided between the plurality of end plate-side refrigerant passages. And a plate-side discharge port. Further, the rotor includes a rotor-side refrigerant passage through which the refrigerant supplied from the end plate-side refrigerant passage flows.

  In this case, when viewed from the axial direction, the end plate-side refrigerant passage of one end plate and the end plate-side refrigerant passage of the other end plate are provided at a different angle or position, and the one end plate is The end plate-side discharge port and the end plate-side discharge port of the other end plate are provided at different angles or positions. Further, the plurality of rotor-side refrigerant passages communicate with an end plate-side refrigerant passage of the one end plate and an end plate-side discharge port of the other end plate, or an end plate of the one end plate. The end discharge port communicates with the end plate side refrigerant passage of the other end plate.

  According to a third aspect of the present invention, the rotating electrical machine according to the first aspect or the second aspect, and cooling the refrigerant discharged to the outside of the rotating electrical machine, and supplying the cooled refrigerant to the refrigerant supply port. And a cooling system for a rotating electric machine having a cooling cooler.

  According to the first aspect of the present invention, by cooling the entire rotating electric machine including the housing, the effect of heat received from the periphery of the rotating electric machine is suppressed, and the rotating electric machine in which an optimal refrigerant path is constructed is realized. can do.

  According to the second aspect of the present invention, since the directions of the refrigerant flowing in the adjacent rotor-side refrigerant passages are different from each other, the temperature gradient along the axial direction of the rotor becomes uniform, so that the cooling performance of the rotor is improved. Is improved. Further, the effect of heat received from the surroundings of the rotating electric machine can be suppressed. Thereby, it is possible to realize a rotating electric machine in which an optimal refrigerant path is constructed.

  According to the third aspect of the present invention, it is possible to efficiently cool the rotating electric machine while efficiently suppressing the influence of heat received from the surroundings of the rotating electric machine.

FIG. 1 is a left side view of an electric vehicle to which a rotating electric machine and a cooling system according to the embodiment are applied. It is sectional drawing of the rotary electric machine of FIG. FIG. 3 is a schematic view of a rotor, a rotor shaft, and a stator of FIG. 2. FIG. 3 is a partially exploded perspective view of the rotating electric machine of FIGS. 1 and 2. 5A and 5B are cross-sectional views taken along lines VA-VA and VB-VB of FIG. 2, respectively. 6A and 6B are a left side view and a right side view of the left end plate of FIGS. 2 and 4, respectively. 7A and 7B are a right side view and a left side view of the right end plate of FIGS. 2 and 4, respectively. FIG. 3 is a perspective view of the housing of FIG. 2. FIG. 4 is a perspective view illustrating a refrigerant path in the rotating electric machine. It is the perspective view which illustrated the scattering of the refrigerant | coolant from the rotor side to the stator side. It is the flowchart which illustrated the path | route of the refrigerant | coolant in a rotary electric machine.

  Hereinafter, preferred embodiments of a rotating electric machine and a cooling system thereof according to the present invention will be described with reference to the accompanying drawings.

[1. Schematic configuration of electric vehicle 14]
FIG. 1 is a left side view of an electric vehicle 14 to which a rotating electric machine 10 and a cooling system 12 according to the present embodiment are applied. In the following description, the front-back, left-right, and up-down directions will be described when viewed from the driver sitting on the seat 16 of the electric vehicle 14.

  The electric vehicle 14 is a straddle-type electric motorcycle and includes a body frame 18. A head pipe 20 is provided at a front end of the body frame 18. The head pipe 20 supports the handle 22 in a steerable manner. The driver operates the front wheel 26 via the front fork 24 by operating the steering wheel 22.

  The battery 28 is housed in a battery case (not shown) supported by the vehicle body frame 18. Behind the vehicle body frame 18, the seat 16 is supported. The rotating electric machine 10 is supported at the rear of the body frame 18 and below the seat 16. An inverter 32 is supported below the vehicle body frame 18. Further, a swing arm 34 is supported at the rear of the body frame 18 so as to be able to swing up and down around a pivot shaft 36. A rear wheel 38 (load) is supported at the rear end of the swing arm 34.

  The rotating electric machine 10 is a brushless motor, and is a driving motor that is driven by the converted AC power when the inverter 32 converts DC power supplied from the battery 28 into AC power. The output shaft 40 of the rotary electric machine 10 protrudes to the left in the vehicle width direction (lateral direction) of the electric vehicle 14. A chain 42 is bridged between the output shaft 40 and the rear wheel 38. The electric vehicle 14 travels by transmitting the output of the rotating electric machine 10 from the output shaft 40 to the rear wheel 38 via the chain 42. On the other hand, at the time of regeneration of the rotating electric machine 10, AC power generated by the rotating electric machine 10 is converted into DC power by the inverter 32, and the battery 28 is charged.

  A pump 44 is disposed on the left side of the rotating electric machine 10. The electric vehicle 14 is equipped with a cooling system 12 for cooling the rotating electric machine 10. The cooling system 12 connects the rotary electric machine 10 to be cooled, a refrigerant cooler 46 supported in a space between a front portion of the body frame 18 and the front wheel 26, and connects the refrigerant cooler 46 and an upper end of the rotary electric machine 10. It comprises a supply pipe (not shown) and a discharge pipe 50 connecting the pump 44 and the refrigerant cooler 46.

  The refrigerant cooler 46 is an air-cooled cooler that cools the refrigerant by wind (traveling wind) from the front while the electric vehicle 14 is traveling. When the pump 44 is driven due to the driving of the rotary electric machine 10, the refrigerant cooled by the refrigerant cooler 46 is supplied to the rotary electric machine 10 via the supply pipe, and the inside of the rotary electric machine 10 is cooled. The pump 44 discharges the refrigerant heated by cooling the inside of the rotary electric machine 10 to the refrigerant cooler 46 via the discharge pipe 50.

  The electric vehicle 14 is covered with a windscreen 52 and a cover member 54 such as a cowl.

[2. Configuration of rotating electric machine 10]
Next, the configuration of the rotating electric machine 10 according to the present embodiment will be described with reference to FIGS.

<2.1 Schematic configuration of rotating electric machine 10>
The rotating electric machine 10 has a housing 60. As shown in FIGS. 2 and 8, the housing 60 extends in the left-right direction, has a large opening on the right side, and has a bottomed cylindrical housing body 60 b formed with a wall 60 a on the left side, and an opening in the housing body 60 b. And a left cover member 60d that covers the wall 60a of the housing body 60b. The housing main body 60b and the right cover member 60c form a first internal space 62 having a relatively large volume. Further, the second internal space 63 having a relatively small volume is formed by the wall portion 60a and the left cover member 60d.

  In the first internal space 62, a rotor 64, a rotor shaft 66, and a stator 68 are housed. The rotor 64 is a cylindrical rotor that extends in the left-right direction (the axial direction of the rotor 64) at the center of the first internal space 62. In addition, the rotor 64 is configured by stacking a plurality of steel plates in the axial direction.

  At both ends in the left-right direction of the rotor 64, two disk-shaped end plates 70L and 70R are provided. As shown in FIGS. 2 and 4, the rotor 64 and the two end plates 70L, 70R are fastened in the left-right direction by screwing a bolt 72 and a nut 74 inserted in the left-right direction.

  The rotor shaft 66 is coaxially connected to the rotor 64 so as to penetrate the two end plates 70L and 70R, and extends in the left-right direction. The left end side of the rotor shaft 66 penetrates through the wall 60a and enters the second internal space 63. In this case, the left end side of the rotor shaft 66 is supported by a bearing 76L disposed on the wall 60a. The right end side of the rotor shaft 66 is supported by a bearing 76R provided on the right cover member 60c.

  As shown in FIGS. 2 and 3, the stator 68 is fixed to the inner peripheral surface of the housing main body 60b between the housing main body 60b and the rotor 64. Therefore, the rotor 64 is an inner rotor and the stator 68 is an outer stator. Note that the stator 68 is configured by stacking a plurality of steel plates in the axial direction. Further, on the inner peripheral surface side of the stator 68, a winding slot 68b for accommodating the winding 68a is provided. Further, the housing 60 houses the rotor 64, the rotor shaft 66, and the stator 68 so as to cover the outer periphery of the stator 68.

  As shown in FIGS. 3 and 4, the rotor 64 has a plurality of magnetic pole slots 80 for accommodating the magnets 78 provided on the outer peripheral surface side of the rotor 64 at predetermined angular intervals. The portion of the magnetic pole slot 80 where the magnet 78 is not housed functions as a flux barrier 82 for suppressing magnetic saturation. Further, a plurality of refrigerant passages 128 (fourth refrigerant passages) to be described later are provided on the inner peripheral surface side of the rotor 64 so as to correspond to the plurality of magnetic pole slots 80. The plurality of magnetic pole slots 80 and the plurality of refrigerant passages 128 extend in the left-right direction as shown in FIGS.

  The shape and number of the winding slots 68 b, the shape and number of the magnetic pole slots 80, and the number of poles of the rotating electric machine 10 shown in FIGS. 3 and 4 may be appropriately set according to the specifications of the rotating electric machine 10. FIGS. 3 and 4 show the 12-pole rotating electric machine 10 as an example, but it is needless to say that the 6-pole or 8-pole rotating electric machine 10 may be used.

  As shown in FIGS. 3, 4, and 6A to 7B, two convex portions 84, 86L, 86R protruding inward are respectively provided on the inner peripheral surfaces of the rotor 64 and the two end plates 70L, 70R. It is formed in the axial direction. Further, as shown in FIGS. 3 to 7B, a plurality of grooves 88 that can be fitted to these convex portions 84, 86 </ b> L, 86 </ b> R are formed on the outer peripheral surface of the rotor shaft 66.

  As shown in FIG. 2, a rotor-side gear 90 is coaxially attached to the left end of the rotor shaft 66 in the second internal space 63. The output shaft 40 is supported by two bearings 92 in the upper part of the second internal space 63. The left end of the output shaft 40 penetrates through the left cover member 60d and protrudes leftward. A reduction gear 94 (an external load gear) that meshes with the rotor-side gear 90 is attached to the right end of the output shaft 40.

  On the other hand, an input shaft 96 of the pump 44 is supported by two bearings 98 in a lower portion of the second internal space 63. The pump 44 is attached to the left cover member 60d, and the input shaft 96 enters the second internal space 63. A pump gear 100 meshing with the rotor-side gear 90 is attached to a distal end (right end) of the input shaft 96. Therefore, the reduction gear 94 and the pump gear 100 are arranged so as to be radially shifted from the rotor-side gear 90 of the rotor shaft 66.

  Near the right end of the rotor shaft 66, a resolver 102 for detecting the rotation angle of the rotor 64 (rotor shaft 66) is provided. The resolver 102 includes a resolver rotor 102a fixed to the right end of the rotor shaft 66, and a resolver stator 102b fixed to the right cover member 60c so as to face the outer peripheral surface of the resolver rotor 102a. Since the configuration and operation of the resolver 102 are well known, a detailed description thereof will be omitted.

<2.2 Characteristic configuration of rotating electric machine 10>
Next, a characteristic configuration of the rotating electric machine 10 according to the present embodiment will be described. The characteristic configuration of the rotating electric machine 10 relates to a path in the rotating electric machine 10 of the refrigerant supplied from the cooling system 12 (see FIG. 1).

  Specifically, as shown in FIGS. 2, 8, and 9, a coolant supply port 110 connected to a supply pipe is provided at an upper end of the housing body 60b.

  The housing 60 is provided with a jacket 112 for cooling the housing 60 with a coolant supplied through a supply pipe and a coolant supply port 110. The jacket 112 is provided between the housing 60 and the stator 68, specifically, on the inner peripheral side of the housing body 60b and inside the right cover member 60c. On the other hand, at the bottom of the housing 60, that is, below the housing main body 60b, a refrigerant storage section 114 for storing the refrigerant dropped from the first internal space 62 is provided. When the refrigerant is oil, the refrigerant storage unit 114 is an oil pan.

  The jacket 112 is provided on the inner peripheral surface side of the housing main body 60b and communicates the refrigerant passage 112a (first refrigerant passage) through which the refrigerant supplied from the refrigerant supply port 110 flows, with the refrigerant passage 112a and the first internal space 62. Then, a refrigerant outlet 112b (first discharge outlet) for discharging the refrigerant flowing through the refrigerant passage 112a to the stator 68 and the right cover member 60c are provided inside, and the refrigerant flowing through the refrigerant passage 112a is branched and supplied to the rotor shaft 66. And a branch passage 112c.

  The coolant passage 112a communicates with the coolant supply port 110 and is provided from the coolant supply port 110 to the coolant storage section 114 along the outer peripheral surface of the stator 68 inside the housing body 60b. That is, the refrigerant passages 112a are provided at predetermined angular intervals inside the housing main body 60b, and a plurality of refrigerant flow passages 116a extending in the left-right direction and a left end or a right end of the housing main body 60b are arranged in a circumferential direction. And a connecting flow path 116b connecting one set of refrigerant flow paths 116a and the other set of refrigerant flow paths 116a. Therefore, one end of the pair of refrigerant channels 116a in the left-right direction is connected to one connection channel 116b, and the other end is connected to the other connection channel 116b.

  As a result, as shown in FIG. 9, the refrigerant passage 112a is provided in an S-shape or a spiral shape so as to entirely face the outer peripheral surface of the stator 68. Also, as shown in FIGS. 2, 8 and 9, the discharge port 112b communicates with the upper and lower two pairs of refrigerant flow paths 116a of the refrigerant passage 112a and the first internal space 62. Preferably, it is formed.

  Note that the refrigerant passage 112a is not limited to the shapes shown in FIGS. 8 and 9, but may be formed in an S-shape or a spiral shape. For example, an S-shaped or spiral cavity formed inside the housing body 60b may be used as the refrigerant passage 112a.

  As shown in FIGS. 2 and 9, the jacket 112 is provided with two branch passages 112c. That is, one branch passage 112c extends obliquely downward and rearward from the front upper right connection passage 116b, and is connected to an internal passage 120a of the rotor shaft 66 described later. The other branch passage 112c extends obliquely downward and forward from the rear upper right connection passage 116b, and is connected to the internal passage 120a of the rotor shaft 66.

  As shown in FIGS. 2 to 5B, 9 and 10, the rotor shaft 66 includes a refrigerant passage 120 (second refrigerant passage) through which the refrigerant supplied from the two branch passages 112c flows. The refrigerant passage 120 is provided in the center of the rotor shaft 66 in the left-right direction, and has an internal flow passage 120a communicating with the branch passage 112c, and a discharge port 120b (third discharge port, rotor shaft Side discharge port) and a plurality of external flow paths 120c provided in the outer peripheral surface of the rotor shaft 66 in the left-right direction. Note that the number of the external channels 120c is the same as the number of the flux barriers 82 described above.

  As shown in FIG. 2, the internal flow passage 120a is provided in a portion corresponding to the first internal space 62, specifically, between two bearings 76L and 76R that support the rotor shaft 66 in the left-right direction. Further, as shown in FIGS. 2 to 7B, the grooves 88 are provided at predetermined angular intervals in the circumferential direction on the outer peripheral surface of the rotor shaft 66, so that the inner peripheral surface of the rotor 64 and each groove 88 form two ends. A plurality of external channels 120c extending in the left-right direction are formed between the plates 70L, 70R. Accordingly, a plurality of external channels 120c are formed radially on the outer peripheral surface of the rotor shaft 66 in a cross-sectional view.

  Each of the plurality of external channels 120c communicates with any one of the plurality of outlets 120b. As shown in FIGS. 2, 4, 5A and 5B, the plurality of discharge ports 120b are provided on the left or right side of the rotor shaft 66. In this case, of the two external channels 120c circumferentially adjacent to the rotor shaft 66, one of the external channels 120c communicates with the left outlet 120b, and the other external channel 120c communicates with the right outlet 120b. Communicating. Therefore, the rotor shaft 66 is provided with an external flow path 120c communicating with the left discharge port 120b and an external flow path 120c communicating with the right discharge port 120b alternately in the circumferential direction. In the vicinity of the two bearings 76L and 76R of the rotor shaft 66, another discharge port 122 that connects the internal flow passage 120a and the first internal space 62 is also formed.

  As shown in FIGS. 2, 4, 6 </ b> A to 7 </ b> B, 9, and 10, the inner portions of the two end plates 70 </ b> L, 70 </ b> R along the left-right direction (the flat portions facing the ends of the rotor 64). Are a plurality of refrigerant passages 124L, 124R (third refrigerant passage, end plate side refrigerant passage) through which refrigerant supplied from a plurality of external flow passages 120c of the rotor shaft 66, and a plurality of discharge ports 126L, 126R (second refrigerant passage). Discharge port). Further, the rotor 64 includes a refrigerant passage 128 through which the refrigerant supplied from the refrigerant passages 124L and 124R of the end plates 70L and 70R flows.

  In this case, a plurality of refrigerant passages 124L, 124R are provided at predetermined angular intervals in the inner portions of the two end plates 70L, 70R, respectively. The plurality of refrigerant passages 124L, 124R are formed to extend radially from the inner peripheral surfaces (rotor shaft 66) of the end plates 70L, 70R when viewed from the left and right directions. Further, the plurality of discharge ports 126L, 126R are formed at predetermined angular intervals so as to be located in the middle of two refrigerant passages 124L, 124R adjacent in the circumferential direction of the end plates 70L, 70R. The two end plates 70L and 70R are each formed with four insertion holes 130 through which the bolts 72 are inserted.

  However, when viewed from the left and right directions, between the two end plates 70L and 70R, the plurality of refrigerant passages 124L and 124R are provided at shifted angles or positions, and the plurality of discharge ports 126L and 126R are shifted at angles or positions. It is provided. That is, in the end plates 70L and 70R, the refrigerant passages 124L and 124R and the discharge ports 126L and 126R are arranged asymmetrically. In short, when viewed from the left and right directions, the plurality of refrigerant passages 124L and the plurality of refrigerant passages 124R do not overlap, and the plurality of outlets 126L and the plurality of outlets 126R do not need to overlap.

  In FIG. 6B, the positions of the refrigerant passage 124R and the discharge port 126R of the right end plate 70R with respect to the refrigerant passage 124L and the discharge port 126L of the left end plate 70L are shown by dashed lines.

  That is, with respect to two adjacent refrigerant passages 128 among the plurality of refrigerant passages 128 formed in the rotor 64, one of the refrigerant passages 128 is formed by the refrigerant passage 124L of the left end plate 70L and the refrigerant passage 124L of the right end plate 70R. It communicates with the discharge port 126R. The other refrigerant passage 128 communicates with the discharge port 126L of the left end plate 70L and the refrigerant passage 124R of the right end plate 70R. That is, the plurality of refrigerant passages 128 of the rotor 64 alternately communicate with the refrigerant passages 124L, 124R and the discharge ports 126L, 126R of the different end plates 70L, 70R along the circumferential direction of the rotor 64.

  Specifically, as shown in FIG. 2, FIG. 6B, FIG. 7B, FIG. 9 and FIG. 10, the refrigerant passage 124L of the left end plate 70L is provided with a plurality of refrigerant passages communicating with the right discharge port 120b of the rotor shaft 66, respectively. It communicates with any one of the external flow paths 120c. The refrigerant passage 124L of the left end plate 70L communicates with one of the discharge ports 126R of the right end plate 70R via any one of the plurality of refrigerant passages 128 of the rotor 64. ing.

  On the other hand, the refrigerant passage 124R of the right end plate 70R communicates with any one of the plurality of external passages 120c communicating with the left discharge port 120b of the rotor shaft 66. The refrigerant passage 124R of the right end plate 70R communicates with one of the discharge ports 126L of the left end plate 70L via any one of the plurality of refrigerant passages 128 of the rotor 64. ing.

  Therefore, with respect to the plurality of refrigerant passages 128 of the rotor 64, one of the two refrigerant passages 128 adjacent in the circumferential direction of the rotor 64 has one of the refrigerant passages 128 whose left end is located at one of the refrigerant passages 124L of the left end plate 70L. The right end communicates with one of the outlets 126R of the right end plate 70L. Further, of the two adjacent refrigerant passages 128, the other refrigerant passage 128 has a right end communicating with one of the refrigerant passages 124R of the right end plate 70R, and a left end having a discharge end of the left end plate 70L. It communicates with one of the outlets 126L.

  Note that the plurality of refrigerant passages 124L, 124R and the plurality of discharge ports 126L, 126R are not limited to the shapes shown in FIGS. 4, 6A to 7B, 9 and 10. Any shape may be used as long as it can communicate with the refrigerant passage 128. Also, the plurality of refrigerant passages 128 are not limited to the shapes shown in FIGS. 3, 4, 9, and 10, as long as the refrigerant can flow in the left and right directions in the rotor 64. Any shape may be used.

[3. Operation of rotating electric machine 10 and cooling system 12]
Next, operations of the rotating electric machine 10 and the cooling system 12 according to the present embodiment will be described with reference to a flowchart of FIG. Note that this operation will be described with reference to FIGS. 1 to 10 as necessary.

  When DC power is supplied from the battery 28 to the inverter 32, the inverter 32 converts the DC power into three-phase AC power, and supplies the converted AC power to the winding 68 a of the stator 68 of the rotating electric machine 10. The supply of AC power to the winding 68a excites the rotor 64, and the rotor 64 and the rotor shaft 66 rotate, so that the rotating electric machine 10 is driven. The rotation of the rotor shaft 66 is transmitted from the rotor gear 90 to the output shaft 40 via the reduction gear 94. The output shaft 40 drives the rear wheel 38 via the chain 42. As a result, the electric vehicle 14 starts running.

  The rotation of the rotor shaft 66 is transmitted from the rotor side gear 90 to the input shaft 96 via the pump gear 100. Accordingly, the pump 44 is driven based on the rotation of the input shaft 96, pumps out the refrigerant (oil) stored in the refrigerant storage unit 114, and starts discharging the refrigerant to the outside. The discharged refrigerant is sent to the refrigerant cooler 46 via the discharge pipe 50. The refrigerant cooler 46 cools the supplied refrigerant by running wind from the front of the electric vehicle 14 and supplies the cooled refrigerant to the refrigerant supply port 110 of the rotating electric machine 10 via a supply pipe. Thereby, cooling of the rotating electric machine 10 by the cooling system 12 is started.

  In the rotating electric machine 10, the refrigerant supplied to the refrigerant supply port 110 flows through the refrigerant passage 112 a of the jacket 112. As described above, the refrigerant passage 112a is formed in an S-shape or a spiral shape on the inner peripheral surface side of the housing body 60b so as to surround the outer peripheral surface of the stator 68 by the pair of refrigerant flow passages 116a and the connection flow passage 116b. Is formed. Therefore, the refrigerant flows along the outer peripheral surface of the stator 68 from the upper end side of the housing main body 60b toward the refrigerant storage section 114 at the bottom of the housing main body 60b through the S-shaped or spiral refrigerant passage 112a. Thus, the housing main body 60b can be cooled while suppressing the transfer of heat from the outside to the inside of the rotating electric machine 10.

  Further, since a plurality of discharge ports 112b are provided on the upper end side of the refrigerant passage 112a, the refrigerant is discharged into the first internal space 62 from each of the discharge ports 112b toward the stator 68. The discharged refrigerant adheres to the windings 68a of the stator 68, so that the windings 68a can be cooled. The refrigerant that has taken heat from the winding 68a falls from the stator 68 below the first internal space 62, and is stored in the refrigerant storage unit 114.

  On the other hand, a part of the refrigerant is supplied to the internal flow passage 120a of the rotor shaft 66 via the branch passage 112c connected to the refrigerant passage 112a. The rotor shaft 66 is cooled by the coolant flowing through the internal flow passage 120a. Further, a plurality of discharge ports 120b and 122 are formed in the rotor shaft 66. Among these, a part of the refrigerant flowing through the internal flow passage 120a is discharged to the first internal space 62 from a plurality of discharge ports 122 formed on the left end side or the right end side of the rotor shaft 66.

  In this case, since the rotor shaft 66 is rotating, the refrigerant is scattered in the radial direction from each of the discharge ports 122 by centrifugal force. As a result, the scattered refrigerant adheres to the bearings 76L, 76R, the stator 68, the outer surface in the vehicle width direction of the rotor 64 (end plates 70L, 70R), the right cover member 60c, and the wall portion 60a of the housing body 60b. And cool these parts. The refrigerant that has taken heat from these parts falls down and is stored in the refrigerant storage unit 114. The coolant attached to the bearings 76L and 76R also lubricates the bearings 76L and 76R.

  In addition, a part of the refrigerant flowing through the internal flow path 120a flows into any one of the external flow paths 120c through the plurality of discharge ports 120b communicating with the plurality of external flow paths 120c. As described above, the plurality of external flow paths 120c alternately communicate with the left and right discharge ports 120b along the circumferential direction of the rotor shaft 66. Therefore, the flowing direction of the refrigerant between the two adjacent external flow paths 120c is opposite to each other. In FIG. 2, as an example, the refrigerant flows leftward from the right discharge port 120b to the refrigerant passage 124L of the left end plate 70L via the upper external flow path 120c, while the left discharge port 120b The figure shows a case where the refrigerant flows rightward from the right through the lower external flow passage 120c toward the refrigerant passage 124R of the right end plate 70R.

  As described above, between the two end plates 70L and 70R, the refrigerant passages 124L and 124R and the discharge ports 126L and 126R are provided at different angles or positions. As a result, as shown in FIGS. 2, 9, and 10, the refrigerant flows in the two adjacent refrigerant passages 128 in the rotor 64 in different directions. Specifically, with respect to the two refrigerant passages 128 adjacent to each other in the circumferential direction of the rotor 64, in one of the refrigerant passages 128, the refrigerant passage 124L of the one end plate 70L → the one refrigerant passage 128 of the rotor 64 → the other end plate 70R In the other refrigerant passage 128, the refrigerant flows in the order of the refrigerant passage 124R of the other end plate 70R → the other refrigerant passage 128 of the rotor 64 → the discharge port 126L of the one end plate 70L. .

  Then, the refrigerant is discharged from the discharge ports 126L, 126R of the two end plates 70L, 70R to the first internal space 62 in the left-right direction. In this case, since the rotor 64 is rotating, the refrigerant discharged from the plurality of discharge ports 126L and 126R scatters radially outward, that is, toward the stator 68 due to centrifugal force. Thereby, the scattered refrigerant adheres to the stator 68 (the winding 68a), and cools the stator 68. The refrigerant that has taken heat from the stator 68 falls downward and is stored in the refrigerant storage unit 114.

  As described above, the two end plates 70L and 70R shift the directions of the refrigerant so that they alternate in the circumferential direction of the rotor 64 by shifting the angles or positions of the refrigerant passages 124L and 124R and the discharge ports 126L and 126R. I am adjusting. As a result, the rotor 64, the rotor shaft 66, and the stator 68 can be cooled while the thermal gradient in the left-right direction is made uniform as a whole of the rotor 64, the rotor shaft 66, and the stator 68.

  Then, since the pump 44 is driven in accordance with the rotation of the rotor shaft 66, the pump 44 pumps the refrigerant stored in the refrigerant storage unit 114 and sends it to the refrigerant cooler 46 via the discharge pipe 50. Since the cooling system 12 is driven while the electric vehicle 14 is traveling, the inside of the rotating electric machine 10 can be efficiently cooled.

[4. Effects of the present embodiment]
As described above, the rotary electric machine 10 according to the present embodiment includes the rotor 64, the rotor shaft 66 coaxially connected to the rotor 64, and the stator 68. In this case, the rotating electric machine 10 further includes a housing 60, a jacket 112, two end plates 70L and 70R, a refrigerant storage unit 114, and a pump 44.

  The housing 60 houses the rotor 64, the rotor shaft 66, and the stator 68 so as to cover the outer periphery of the stator 68, and includes a refrigerant supply port 110 to which a refrigerant from the outside is supplied. The jacket 112 is provided between the housing 60 and the stator 68, and discharges refrigerant flowing through the refrigerant passage 112 a to the stator 68 and a refrigerant passage 112 a (first refrigerant passage) through which the refrigerant supplied from the refrigerant supply port 110 flows. It has a discharge port 112b (first discharge port) and a branch path 112c that branches the refrigerant flowing through the refrigerant path 112a and supplies the refrigerant to the rotor shaft 66. The rotor shaft 66 includes a refrigerant passage 120 (second refrigerant passage) through which the refrigerant supplied from the branch passage 112c flows. The two end plates 70L, 70R are provided at both ends in the axial direction of the rotor 64, and include refrigerant passages 124L, 124R (third refrigerant passages) through which the refrigerant supplied from the refrigerant passage 120 of the rotor shaft 66 flows. The refrigerant storage unit 114 is provided at the bottom of the housing 60, and stores the refrigerant in the housing 60. The pump 44 is driven according to the rotation of the rotor 64 to discharge the refrigerant stored in the refrigerant storage unit 114 to the outside.

  Thus, the entire rotating electric machine 10 including the housing 60 is cooled, and the effect of heat received from the surroundings of the rotating electric machine 10 is suppressed, and the rotating electric machine 10 in which an optimal refrigerant path is constructed can be realized. In addition, since the passage of the refrigerant is formed in each part constituting the rotating electric machine 10, the inside of the rotating electric machine 10 can be uniformly cooled. Further, by providing the jacket 112 between the housing 60 and the stator 68, specifically, on the inner peripheral surface side of the housing 60, the entire rotating electric machine 10 can be actively cooled. Furthermore, since the pump 44 can supply the refrigerant at an appropriate flow rate from the refrigerant cooler 46 to the rotating electric machine 10 in accordance with the rotation of the rotor 64, higher cooling performance can be realized.

  Further, the rotor 64 includes a refrigerant passage 128 (fourth refrigerant passage) through which the refrigerant supplied from the refrigerant passages 124L and 124R of the two end plates 70L and 70R flows. On the other hand, the two end plates 70L and 70R further include discharge ports 126L and 126R (second discharge ports) for discharging the refrigerant flowing through the refrigerant passage 128 of the rotor 64 to the stator 68. Accordingly, the rotor 64 can be efficiently cooled, and the refrigerant discharged from the discharge ports 126L and 126R is scattered to the stator 68 by centrifugal force due to the rotation of the rotor 64, so that the stator 68 can be cooled efficiently. .

  In this case, the refrigerant passage 120 of the rotor shaft 66 is provided in the rotor shaft 66 in the axial direction, and has an internal flow passage 120a through which the refrigerant supplied from the branch passage 112c flows, and a diameter of the rotor shaft 66 from the internal flow passage 120a. A discharge port 120b (third discharge port) that opens in the direction, and a refrigerant that is provided in the axial direction on the outer peripheral surface of the rotor shaft 66 and that is supplied from the internal flow passage 120a through the discharge port 120b to the end plates 70L and 70R. The refrigerant passages 124 </ b> L and 124 </ b> R or the external passage 120 c flowing through the rotor 64 are configured. Thereby, the cooling of the rotor shaft 66, the rotor 64, and the end plates 70L and 70R can be performed efficiently.

  Further, a plurality of external channels 120c are radially formed on the outer peripheral surface of the rotor shaft 66 in a cross-sectional view, and the plurality of external channels 120c are respectively formed by a plurality of discharge ports 120b formed on the rotor shaft 66. Of these, it communicates with any one of the outlets 120b. Accordingly, the rotor 64 and the rotor shaft 66 can be cooled while efficiently flowing the refrigerant through the plurality of external flow paths 120c.

  In the rotor 64, a plurality of refrigerant passages 128 extending in the axial direction are formed radially when viewed from the axial direction. On the other hand, in the two end plates 70L and 70R, a plurality of refrigerant passages 124L and 124R are formed radially from the rotor shaft 66 when viewed from the axial direction, and a discharge port is provided between the plurality of refrigerant passages 124L and 124R. 126L and 126R are provided. In this case, when viewed from the axial direction, the refrigerant passage 124L of the one end plate 70L and the refrigerant passage 124R of the other end plate 70R are provided at different angles or positions, and the discharge port 126L of the one end plate 70L is provided. And the discharge port 126R of the other end plate 70R are provided at different angles or positions. The plurality of refrigerant passages 128 of the rotor 64 communicate with the refrigerant passage 124L of the one end plate 70L and the discharge port 126R of the other end plate 70R, respectively, or the discharge port 126L of the one end plate 70L. And the refrigerant passage 124R of the other end plate 70R.

  That is, by shifting the angles or positions of the refrigerant passages 124L, 124R of the two end plates 70L, 70R, the flow direction of the refrigerant in the plurality of refrigerant passages 128 of the rotor 64 can be adjusted. As a result, when viewed from the axial direction, the flowing direction of the refrigerant in the plurality of refrigerant passages 128 of the rotor 64 is alternately different. As a result, the heat gradient along the axial direction inside the housing 60 can be made uniform, so that the inside of the rotary electric machine 10 can be cooled more efficiently.

In this case, the rotor 64 is provided with a plurality of magnetic pole slots 80 for accommodating the magnets 78, and the plurality of refrigerant passages 128 of the rotor 64 are provided on the rotor 64 corresponding to the plurality of magnetic pole slots 80. This makes it possible to cool the magnet 78 of the multiple efficiently.

  The coolant passage 112a of the jacket 112 is provided in an S-shape or spiral so as to face the outer peripheral surface of the stator 68. Thereby, the housing 60 can be efficiently cooled while blocking the transfer of heat from the outside to the inside of the rotary electric machine 10.

  In this case, the coolant supply port 110 is provided at an upper end portion of the housing 60, and the coolant passage 112 a is provided inside the housing 60 along the outer peripheral surface of the stator 68 from the coolant supply port 110 toward the coolant storage section 114. The branch passage 112c is provided from the upper part of the refrigerant passage 112a toward the rotor shaft 66. As described above, the passage of the refrigerant is provided from above to below the housing 60, so that the inside of the rotary electric machine 10 can be cooled more efficiently.

  The rotating electric machine 10 is connected to one side of the rotor shaft 66 in the housing 60, and is connected to a pump gear 100 for transmitting rotation of the rotor shaft 66 to the pump 44, and to one side of the rotor shaft 66 in the housing 60. And a reduction gear 94 (external load gear) for transmitting the rotation of the rotor shaft 66 to the rear wheel 38 (load). Thus, since two gears for driving the load are arranged on one side of the rotor shaft 66, the rotating electric machine 10 can be made compact.

  In this case, the rotating electric machine 10 is a motor for driving the electric vehicle 14, the rear wheel 38 of the electric vehicle 14 is a load of the rotating electric machine 10, and the reduction gear 94 and the pump gear 100 are radially moved from the rotor shaft 66. Are shifted from each other. Accordingly, the degree of freedom in setting the position of the output shaft 40 is increased, and the rotating electric machine 10 can be designed with an optimal layout. In particular, in the case of the electric vehicle 14 in which the rear wheel 38 is driven from the output shaft 40 via the chain 42, an optimal layout design can be realized.

  Further, both axial sides of the rotor shaft 66 are supported in the housing 60 via bearings 76L and 76R, respectively. Further, since the refrigerant is oil, lubrication of the two bearings 76L and 76R and cooling of the housing 60, the rotor 64, the rotor shaft 66 and the stator 68 can be performed efficiently.

  The refrigerant discharged to the outside of the rotating electric machine 10 by the pump 44 is cooled by the external refrigerant cooler 46, and the cooled refrigerant is supplied to the refrigerant supply port 110. Thereby, the rotating electric machine 10 can be efficiently cooled.

  In this case, the rotating electric machine 10 is a motor for driving the electric vehicle 14, and the refrigerant cooler 46 is disposed in front of the body frame 18 of the electric vehicle 14. This allows the refrigerant to be efficiently cooled by the wind received from the front while the electric vehicle 14 is traveling. Further, the cooling performance for the rotating electric machine 10 can be improved according to the operating state of the electric vehicle 14.

  Further, since the electric vehicle 14 is an electric motorcycle, the rotating electric machine 10 and the cooling system described above can be appropriately arranged on the electric motorcycle.

  Further, the rotor 64 is an inner rotor provided with a magnetic pole slot 80 for housing a magnet 78, the stator 68 is an outer stator provided with a winding slot 68b for housing a winding 68a, and the rotating electric machine 10 It is a brushless motor. Thereby, the configuration of the cooling system described above can be appropriately arranged.

  In addition, the rotating electric machine 10 according to the present embodiment includes a rotor 64, a rotor shaft 66 coaxially connected to the rotor 64, a stator 68, and two end plates 70L provided at both axial ends of the rotor 64, 70R.

  In this case, the rotor shaft 66 is provided inside the rotor shaft 66 in the axial direction, and has an internal flow passage 120a through which a refrigerant supplied from the outside flows, and a discharge port opened in the radial direction of the rotor shaft 66 from the internal flow passage 120a. 120b (rotor shaft side discharge port), and an externally provided coolant which is provided in the axial direction on the outer peripheral surface of the rotor shaft 66 and which is supplied from the internal flow passage 120a through the discharge port 112b to the end plates 70L, 70R or the rotor 64. And a flow channel 120c.

  The two end plates 70L and 70R are between a plurality of refrigerant passages 124L and 124R (end plate side refrigerant passages) formed radially from the rotor shaft 66 when viewed from the axial direction, and a plurality of refrigerant passages 124L and 124R, respectively. Discharge ports 126L and 126R (end plate side discharge ports) provided at the bottom of the printer. Further, the rotor 64 includes a refrigerant passage 128 (rotor-side refrigerant passage) through which the refrigerant supplied from the refrigerant passages 124L and 124R of the end plates 70L and 70R flows.

  In this case, when viewed from the axial direction, the refrigerant passage 124L of the one end plate 70L and the refrigerant passage 124R of the other end plate 70R are provided at different angles or positions, and the discharge port 126L of the one end plate 70L is provided. And the discharge port 126R of the other end plate 70R are provided at different angles or positions. Further, the plurality of refrigerant passages 128 of the rotor 64 communicate with the refrigerant passage 124L of the one end plate 70L and the discharge port 126R of the other end plate 70R, or with the discharge port 126L of the one end plate 70L and the other. And the refrigerant passage 124R of the end plate 70R.

  Thereby, in the rotor 64, the directions of the refrigerant flowing in the adjacent refrigerant passages 128 are different from each other, so that the temperature gradient along the axial direction of the rotor 64 becomes uniform, and the cooling performance of the rotor 64 is improved. Further, the influence of heat received from the surroundings of the rotating electric machine 10 can be suppressed. Thereby, it is possible to realize the rotating electric machine 10 in which an optimal refrigerant path is constructed.

  Further, the cooling system 12 according to the present embodiment includes the above-described rotating electric machine 10 and the refrigerant cooler 46 that cools the refrigerant discharged to the outside of the rotating electric machine 10 and supplies the cooled refrigerant to the refrigerant supply port 110. Have. This makes it possible to efficiently cool the rotating electric machine 10 while efficiently suppressing the influence of heat received from the surroundings of the rotating electric machine 10.

  Note that the present invention is not limited to the above-described embodiment, but can adopt various configurations based on the contents described in this specification.

Reference Signs List 10 rotating electric machine 12 cooling system 44 pump 46 refrigerant cooler 60 housing 64 rotor 66 rotor shaft 68 stator 70L, 70R end plate 110 refrigerant supply port 112 jacket 112a refrigerant passage (first refrigerant) aisle)
112b ... discharge port (first discharge port) 112c ... branch path 114 ... refrigerant storage section 120 ... refrigerant path (second refrigerant path)
120a ... internal flow path 120b ... discharge port (third discharge port, discharge port on rotor shaft side)
120c ... external flow paths 124L, 124R ... refrigerant passages (third refrigerant passage, end plate-side refrigerant passage)
126L, 126R ... Discharge port (second discharge port, end plate side discharge port)
128: refrigerant passage (fourth refrigerant passage, rotor-side refrigerant passage)

Claims (15)

A rotating electric machine having a rotor, a rotor shaft coaxially connected to the rotor, and a stator,
It said rotor so as to cover the outer circumference of the stator, and houses the rotor shaft and the stator, a housing having a coolant supply port refrigerant is supplied,
A first refrigerant passage provided between the housing and the stator, through which the refrigerant supplied from the refrigerant supply port flows;
A second refrigerant passage provided in the rotor shaft,
A jacket provided with at least two branch passages for branching the refrigerant flowing through the first refrigerant passage at different positions and supplying the refrigerant to the second refrigerant passage through different routes ;
Respectively provided in the axial direction of both ends of the front SL rotor, and two end plates with a third coolant passage for flowing the refrigerant supplied from the second refrigerant passage,
A fourth refrigerant passage provided through the rotor and flowing the refrigerant from the third refrigerant passage of one end plate to a discharge port opened in the housing at the other end plate;
A refrigerant storage unit provided at the bottom of the housing, for storing the refrigerant in the housing;
Is driven according to the rotation of the rotor, while discharging the refrigerant accumulated in the refrigerant reservoir to the outside, a pump for supplying the coolant supply port,
A rotating electric machine further comprising: The rotating electric machine according to claim 1 ,
The coolant supply port is provided at an upper end of the housing,
The first refrigerant passage is provided from the refrigerant supply port toward the refrigerant storage portion along the outer peripheral surface of the stator inside the housing,
Two of the branch passages, when viewed from the axial direction, are provided in a V-shape from the upper portion of the first refrigerant passage Migihitsuji suited to the second refrigerant passage, the rotary electric machine. A rotating electric machine having a rotor, a rotor shaft coaxially connected to the rotor, and a stator ,
A housing that houses the rotor, the rotor shaft and the stator so as to cover the outer periphery of the stator, and includes a refrigerant supply port to which a refrigerant is supplied;
A first refrigerant passage provided between the housing and the stator, through which the refrigerant supplied from the refrigerant supply port flows;
A second refrigerant passage provided in the rotor shaft,
A jacket including a branch passage that branches the refrigerant flowing through the first refrigerant passage and supplies the branched refrigerant to the second refrigerant passage;
Two end plates provided at both ends in the axial direction of the rotor and including a third refrigerant passage through which the refrigerant supplied from the second refrigerant passage flows,
A fourth refrigerant passage provided through the rotor and flowing the refrigerant from the third refrigerant passage of one end plate to a discharge port opened into the housing at the other end plate ;
A refrigerant storage unit provided at the bottom of the housing, for storing the refrigerant in the housing;
A pump that is driven according to the rotation of the rotor and discharges the refrigerant stored in the refrigerant storage unit to the outside, and supplies the refrigerant to the refrigerant supply port,
Further having
The fourth refrigerant passage extends in a long hole shape along a radial direction of the rotor as viewed from the axial direction, and is provided in a plurality in a radial manner at intervals in a circumferential direction of the rotor,
Plurality of said discharge ports of two of said end plates, for ejecting the refrigerant flowing through the fourth refrigerant passage in the stator, the rotating electrical machine. The rotating electric machine according to claim 3,
The rotating electric machine, wherein the plurality of discharge ports of the two end plates are opened in the housing so as to communicate with the radially outer portion of the fourth refrigerant passage. The rotating electric machine according to claim 3 or 4 ,
A plurality of magnetic pole slots for accommodating magnets are provided in a radially outer portion of the rotor than the plurality of fourth refrigerant passages ,
In each of the plurality of fourth refrigerant passages , when viewed from the axial direction, a center line extending in the radial direction of the fourth refrigerant passage passes between two circumferentially adjacent magnetic pole slots . A rotating electric machine provided to the rotor as described above. A rotating electric machine having a rotor, a rotor shaft coaxially connected to the rotor, and a stator ,
A housing that houses the rotor, the rotor shaft and the stator so as to cover the outer periphery of the stator, and includes a refrigerant supply port to which a refrigerant is supplied;
A first refrigerant passage provided between the housing and the stator, through which the refrigerant supplied from the refrigerant supply port flows;
A second refrigerant passage provided in the rotor shaft,
A jacket including a branch passage that branches the refrigerant flowing through the first refrigerant passage and supplies the branched refrigerant to the second refrigerant passage;
Two end plates provided at both ends in the axial direction of the rotor and including a third refrigerant passage through which the refrigerant supplied from the second refrigerant passage flows,
A fourth refrigerant passage that is provided through the rotor and flows the refrigerant from the third refrigerant passage of one end plate to an end plate-side discharge port that opens into the housing at the other end plate;
A refrigerant storage unit provided at the bottom of the housing, for storing the refrigerant in the housing;
A pump that is driven according to the rotation of the rotor and discharges the refrigerant stored in the refrigerant storage unit to the outside, and supplies the refrigerant to the refrigerant supply port,
Further having
The rotor is provided with a plurality of magnetic pole slots for housing magnets,
In the rotor shaft, a rotor shaft side discharge port is opened in a radial direction of the rotor,
On the outer peripheral surface of the rotor shaft, a plurality of external flow paths for flowing the refrigerant supplied from the second refrigerant passage through the discharge port on the rotor shaft side to the third refrigerant passage or the rotor are provided.
The plurality of external flow paths are a plurality of grooves formed radially in a cross-sectional view,
The plurality of external flow paths are arranged so as to correspond to the plurality of magnetic pole slots, and are provided on the outer peripheral surface of the rotor shaft by the number of the plurality of magnetic pole slots,
The plurality of the external channel, respectively, among the plurality of rotor shaft side discharge port communicates with one of the rotor shaft side discharge port, the rotary electric machine. The rotating electric machine according to claim 6 ,
The second refrigerant passage,
An internal flow path that is provided in the axial direction inside the rotor shaft and flows the refrigerant supplied from the branch path,
A plurality of said rotor shaft side discharge port opening in the radial direction from the inner flow channel inside two of said end plates in the rotor shaft,
An outer side of the two end plates of the rotor shaft, and an inner side of a bearing that supports the both sides of the rotor in the axial direction in the housing; A plurality of outer discharge ports for discharging the refrigerant supplied from the flow path into the housing,
A plurality of external flow paths provided in the axial direction on the outer peripheral surface of the rotor shaft,
A rotating electric machine composed of: A rotating electric machine having a rotor, a rotor shaft coaxially connected to the rotor, and a stator ,
A housing that houses the rotor, the rotor shaft and the stator so as to cover the outer periphery of the stator, and includes a refrigerant supply port to which a refrigerant is supplied;
A first refrigerant passage provided between the housing and the stator, through which the refrigerant supplied from the refrigerant supply port flows;
A second refrigerant passage provided in the rotor shaft,
A jacket including a branch passage that branches the refrigerant flowing through the first refrigerant passage and supplies the branched refrigerant to the second refrigerant passage;
Two end plates respectively provided at both ends in the axial direction of the rotor and including a third refrigerant passage through which the refrigerant supplied from the second refrigerant passage flows;
A fourth refrigerant passage that is provided through the rotor and flows the refrigerant from the third refrigerant passage of one end plate to a discharge port that opens into the housing at the other end plate;
A refrigerant storage unit provided at the bottom of the housing, for storing the refrigerant in the housing;
A pump that is driven according to the rotation of the rotor and discharges the refrigerant stored in the refrigerant storage unit to the outside, and supplies the refrigerant to the refrigerant supply port,
Further having
It said rotor poles slots plurality et been for housing the magnet,
In each of the two end plates, a plurality of the third coolant passages each corresponding to a half of a plurality of the magnetic pole slots are formed radially from the rotor shaft when viewed from the axial direction, and a plurality of the third coolant passages are formed. 3 as many previous Ki吐 outlet of the half between the refrigerant passage is provided,
As viewed from the axial direction, and the third refrigerant passage of one of the end plates, together with the said third refrigerant passage of the other of said end plates is provided by shifting the angle or position, the said one end plate and discharge opening, said discharge opening of said other end plate is provided by shifting the angle or position,
A plurality of the fourth refrigerant passage, respectively, the third refrigerant passage of the one end plate is communicated with the discharge opening of the other end plate, or, the third refrigerant passage of the previous SL other end plate wherein is communicated with the discharge port of one of the end plates,
The opening area of the plurality of discharge ports is smaller than the flow path area of the fourth refrigerant passage,
The rotating electric machine , wherein the plurality of discharge ports communicate with a radially outer portion of the rotor in the fourth refrigerant passage . The rotating electric machine according to any one of claims 1 to 8 ,
The rotating electric machine, wherein the first refrigerant passage is provided in an S-shape or a spiral shape so as to face an outer peripheral surface of the stator. The rotating electric machine according to any one of claims 1 to 9 ,
A single rotor gear coupled to the end of the rotor shaft within the housing ;
A pump gear for transmitting rotation of the rotor shaft from the rotor gear to the pump,
An external load gear that is disposed at a position symmetrical to the pump gear with the rotor shaft interposed therebetween and that transmits rotation of the rotor shaft from the rotor gear to an external load;
Further comprising a,
The rotor gear distributes the driving force of the rotating electric machine to the pump gear and the external load gear,
The rotating electric machine is a driving motor for an electric vehicle,
The load is a wheel of the electric vehicle,
The external load gear is a reduction gear,
A rotating electric machine, wherein the rotor gear, the pump gear, and the external load gear are arranged so as to be aligned in a plan view and a side view. The rotating electric machine according to any one of claims 1 to 10,
Both sides of the rotor shaft in the axial direction are supported in the housing via bearings, respectively.
The rotating electric machine, wherein the refrigerant is oil that lubricates the two bearings and cools the housing, the rotor, the rotor shaft, and the stator. The rotating electric machine according to any one of claims 1 to 11,
The refrigerant is discharged to the outside of the rotating electric machine by the pump, and cooled by an external refrigerant cooler,
A rotating electric machine, wherein the cooled refrigerant is supplied to the refrigerant supply port. The rotating electric machine according to claim 12,
The rotating electric machine is a driving motor for an electric vehicle,
The rotating electric machine, wherein the refrigerant cooler is disposed in front of a body of the electric vehicle. The rotating electric machine according to any one of claims 1 to 13 ,
The rotor is an inner rotor provided with a magnetic pole slot for housing a magnet,
The stator is an outer stator provided with a winding slot for storing a winding,
The rotating electric machine, wherein the rotating electric machine is a brushless motor. A rotating electric machine according to any one of claims 1 to 14 , and a refrigerant cooler configured to cool the refrigerant discharged outside the rotating electric machine and supply the cooled refrigerant to the refrigerant supply port. And the rotating electric machine is a drive motor of an electric motorcycle, a cooling system of the rotating electric machine,
A cooling system for a rotating electric machine, wherein the refrigerant cooler is arranged behind a front fork of the electric motorcycle and below a handle .

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