JP2013062926A - Rotary electric machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve cooling performance of a stator even when rotation of a rotor is locked while cooling the stator by supplying the stator with coolant passing inside a rotation axis of the rotor.SOLUTION: Discharge pressure of an oil pump 50 supplies a coolant passage 49 in a rotation axis 13 with coolant oil and the coolant oil is spouted out from each coolant discharge opening 48 toward a coil end part 22a. Moreover, reaction of a blowout force of the coolant oil from each of the coolant discharge openings 48 in parallel with a tangent line in a rotor circumferential direction causes a coolant discharge device 42 to rotate relative to the rotation axis 13 and a rotor 14 in an opposite direction of the blowout direction of the coolant oil. Thus, a circumferential position of a coolant oil supply in the coil end part 22a varies according to rotation of the coolant discharge device 42 even when rotation of the rotor 14 is locked.

Description

  The present invention relates to a rotating electrical machine in which a stator is disposed opposite to a rotor on the outer peripheral side of the rotor, and more particularly to cooling of the stator.

  In a rotating electrical machine, a technique for cooling a stator and a rotor by flowing refrigerant oil passing through a rotor shaft by centrifugal force when the rotor rotates is known. For example, in Patent Document 1 below, an oil passage for circulating refrigerant oil is formed in the rotor shaft, and an oil passage communicating with the oil passage is provided at at least one end in the axial direction of the rotor. It is formed through the plate, and at the open end of the oil passage, the radius of the rotor is reduced by centrifugal force so that the flow resistance of the refrigerant oil flowing out from the open end decreases as the rotational speed of the rotor increases. An elastic member that deforms outward in the direction is provided. When the rotor rotates at low speed, the centrifugal force acting on the elastic member is small and the straight pipe state is maintained. The refrigerant oil receives centrifugal force according to the number of rotations of the rotor, whereas the refrigerant oil flows out of the elastic member. Since the direction is the axial direction of the rotor, the flow resistance of the refrigerant oil in the elastic member is increased. On the other hand, when the rotor rotates at a high speed, the centrifugal force acting on the elastic member increases, and the tip end side of the rotor elastically bends outward in the radial direction of the rotor. The flow resistance of the refrigerant oil at the member is reduced. As a result, when the rotor rotates at a high speed, the flow rate of the refrigerant oil increases, and the amount of heat that the refrigerant oil takes away increases.

JP 2011-87434 A JP 2011-122711 A

  In Patent Document 1, it is possible to cool the stator by supplying refrigerant oil discharged from the elastic member to the stator (for example, a stator coil) by centrifugal force when the rotor rotates. However, in that case, for example, when the rotation of the rotor is locked due to a high load applied to the rotor, the refrigerant oil is discharged from the elastic member only in a certain direction (vertically downward), and the stator is uniformly cooled. It becomes difficult. As a result, the cooling performance of the stator is reduced, and the temperature of the stator varies.

  The rotating electrical machine according to the present invention improves the cooling performance of the stator even when the rotation of the rotor is locked, when cooling the stator by supplying the refrigerant passing through the rotation shaft of the rotor to the stator. Objective.

  The rotating electrical machine according to the present invention employs the following means in order to achieve the above-described object.

  A rotating electrical machine according to the present invention is directed to a rotor that rotates together with a rotating shaft, a stator that is disposed opposite to the rotor on the outer peripheral side of the rotor, and a refrigerant that is supplied from a refrigerant passage formed on the rotating shaft toward the stator. A refrigerant discharge device having a refrigerant discharge port for discharging and capable of rotating relative to the rotating shaft and the rotor, wherein the refrigerant discharge device has a flow rate of the refrigerant discharged from the refrigerant discharge port parallel to a tangent in the circumferential direction of the rotor. The gist is to rotate relative to the rotation shaft and the rotor by discharging the refrigerant from the refrigerant discharge port so as to have a velocity component in the direction.

  In one aspect of the present invention, it is preferable that the refrigerant discharge device rotate relative to the rotation shaft and the rotor by discharging the refrigerant from the refrigerant discharge port in a direction parallel to the tangential line in the circumferential direction of the rotor.

  In one aspect of the present invention, the refrigerant discharge device has a plurality of refrigerant discharge ports, the plurality of refrigerant discharge ports are arranged at intervals from each other in the rotor circumferential direction, and the refrigerant discharge device discharges from each refrigerant discharge port. Each refrigerant flow rate has a speed component in the rotor circumferential speed direction, or each refrigerant flow rate discharged from each refrigerant discharge port has a speed component in the direction opposite to the rotor circumferential speed direction. By discharging the refrigerant, it is preferable to rotate relative to the rotating shaft and the rotor.

  In one aspect of the present invention, it is preferable that the refrigerant discharge device is rotatably supported on the rotation shaft at the outer end in the rotation axis direction of the rotor.

  According to the present invention, while supplying the refrigerant from the refrigerant discharge port to the stator, the reaction of the refrigerant discharge force from the refrigerant discharge port is used to make the refrigerant discharge device reverse to the refrigerant discharge direction with respect to the rotating shaft and the rotor. It can be rotated relative to the direction. Therefore, even when the rotation of the rotor is locked, the circumferential position of the stator where the refrigerant is supplied can be changed according to the rotation of the refrigerant discharge device, and the cooling performance of the stator can be improved.

It is a figure which shows schematic structure of the rotary electric machine which concerns on embodiment of this invention. It is a figure which shows schematic structure of the rotary electric machine which concerns on embodiment of this invention. It is a figure which shows schematic structure of the rotary electric machine which concerns on embodiment of this invention. It is a figure which shows schematic structure of the rotary electric machine which concerns on embodiment of this invention.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments for carrying out the present invention (hereinafter referred to as embodiments) will be described with reference to the drawings.

  1 and 2 are diagrams illustrating a schematic configuration of a rotating electrical machine according to an embodiment of the present invention. FIG. 1 illustrates an internal configuration viewed from a direction orthogonal to an axial direction of a rotating shaft 13 (hereinafter referred to as a rotating shaft direction). FIG. 2 shows an outline of an internal configuration viewed from the direction of the rotation axis. The rotating electrical machine includes a stator 12 whose rotation is fixed and a rotor 14 that can rotate relative to the stator 12. The stator 12 is disposed on the outer peripheral side of the rotor 14, and is stator in a radial direction orthogonal to the rotation axis direction. 12 and the rotor 14 are arranged to face each other with a predetermined minute gap.

  The rotor 14 is provided at a rotor core 31 fixed to the rotation shaft 13, a plurality of permanent magnets 32 disposed along the circumferential direction of the rotor core 31, and outer ends (both ends) in the rotation axis direction of the rotor core 31. And a pair of end plates 33 that sandwich the rotor core 31 in the rotation axis direction. The stator 12 includes a stator core 21 and a plurality of (for example, three-phase) stator coils 22 disposed on the stator core 21 along the circumferential direction thereof. A plurality of teeth 23 protruding radially inward (toward the rotor 14) are arranged on the stator core 21 at intervals (equal intervals) along the circumferential direction, and slots are formed between the teeth 23. Is formed. The stator coil 22 is wound around the tooth 23 through the slot between the teeth 23, so that the stator 12 has a magnetic pole. The stator coil 22 has a coil end portion 22a that is a portion projecting outward (both sides) from the stator core 21 (tooth 23) in the rotational axis direction, and the coil end portion 22a is outside (both sides) from the rotor 14 in the rotational axis direction. Overhangs.

  In the rotating electrical machine, a rotating magnetic field that rotates in the circumferential direction is formed in the stator 12 by passing an alternating current through the stator coil 22. The rotor 14 is rotated by applying torque (magnet torque) to the rotor 14 by electromagnetic interaction (attraction and repulsion) between the rotating magnetic field generated in the stator 12 and the field magnetic flux generated in the permanent magnet 32 of the rotor 14. It can be rotated together with the shaft 13. Thus, the rotating electrical machine can function as an electric motor that generates power in the rotor 14 using the power supplied to the stator coil 22. On the other hand, the rotating electrical machine can also function as a generator that generates power in the stator coil 22 using the power of the rotor 14. The rotor 14 is not limited to the configuration in which the permanent magnet 32 is provided. For example, the rotor 14 may have a configuration in which a coil is provided or a configuration in which reluctance torque is used by a change in magnetic resistance.

  In this embodiment, in order to cool the stator 12 (mainly the stator coil 22) with the refrigerant oil, the refrigerant discharge device 42 is provided at the outer end in the rotation axis direction of the rotor 14 (end plate 33). In the example shown in FIG. 1, the refrigerant discharge devices 42 are provided at both ends in the rotation axis direction of the rotor 14, but the refrigerant discharge devices 42 may be provided only at one end in the rotation axis direction of the rotor 14. Hereinafter, a configuration example of the refrigerant discharge device 42 will be described.

  The refrigerant discharge device 42 includes a plurality (four in the example shown in FIG. 2) of refrigerant discharge pipes 44 that are spaced apart from each other (equal intervals) in the circumferential direction of the rotor, and the refrigerant flow in each refrigerant discharge pipe 44. An annular refrigerant distribution pipe 46 for guiding refrigerant oil to the passage 45 is provided, and is arranged on the inner peripheral side of the coil end portion 22 a of the stator coil 22. Since the end of each refrigerant discharge pipe 44 on the center side in the rotor radial direction is connected to the refrigerant distribution pipe 46, the refrigerant flow path 45 in each refrigerant discharge pipe 44 is connected to the refrigerant flow path 47 in the refrigerant distribution pipe 46. Communicate. An end of each refrigerant discharge pipe 44 (refrigerant flow path 45) on the outer side in the rotor radial direction is opened to the outside and functions as a refrigerant discharge port 48 for discharging refrigerant oil. The refrigerant distribution pipe 46 of the refrigerant discharge device 42 is rotatably supported on the rotary shaft 13 via the bearing 41, so that the refrigerant discharge device 42 (each refrigerant discharge pipe 44 and the refrigerant distribution pipe 46) It can rotate relative to the rotor 14. In addition, when using a rotary electric machine as a power source of a hybrid vehicle, it is also possible to use, for example, ATF (Automatic Transmission Fluid) as refrigerant oil.

  In order to supply the refrigerant oil to the refrigerant discharge device 42, a refrigerant flow path 49 is formed along the axial direction in the rotary shaft 13, and the refrigerant oil discharged from the oil pump 50 is the refrigerant in the rotary shaft 13. Supplied to the flow path 49. In FIG. 1, illustration of a specific configuration for supplying the refrigerant oil from the oil pump 50 to the refrigerant flow path 49 in the rotary shaft 13 is omitted, but this can be realized with a known configuration. As shown in FIG. 3, a plurality of (four in the example shown in FIG. 3) refrigerant discharge holes 52 are formed in the end plate 33 at regular intervals with respect to the rotor circumferential direction. Each refrigerant discharge hole 52 of the end plate 33 communicates with the refrigerant flow path 49 in the rotating shaft 13 via the refrigerant flow path 51 in the rotor core 31, so that the refrigerant flow as shown by an arrow A in FIG. The refrigerant oil supplied to the passage 49 flows out from each refrigerant discharge hole 52 through the refrigerant flow path 51.

  As shown in FIG. 4, the refrigerant distribution pipe 46 is formed with a refrigerant inflow port 53 communicating with the refrigerant flow path 47 so as to face each refrigerant discharge hole 52 of the end plate 33 in the rotation axis direction. Refrigerant oil does not leak to the outside and flows from the respective refrigerant discharge holes 52 to the refrigerant inlet 53 at the relative rotation portion between each refrigerant discharge hole 52 of the end plate 33 and the refrigerant inlet 53 of the refrigerant distribution pipe 46. Thus, annular seal rings (seal members) 54 and 56 are provided for liquid-tight sealing. The seal ring 54 is mounted at a position on the inner peripheral side from each refrigerant discharge hole 52 and the refrigerant inlet 53, and the seal ring 56 is mounted at a position on the outer peripheral side from each refrigerant discharge hole 52 and the refrigerant inlet 53. . The seal rings 54 and 56 permit the relative rotation of the refrigerant discharge device 42 (refrigerant distribution pipe 46) with respect to the rotor 14 (end plate 33), and the refrigerant in the refrigerant discharge holes 52 of the end plate 33 and the refrigerant distribution pipe 46. It is possible to seal the communication portion with the inflow port 53, and as shown by an arrow F in FIG. 4, the refrigerant oil passes through the refrigerant inflow port 53 of the refrigerant distribution pipe 46 from each refrigerant discharge hole 52 of the end plate 33. The refrigerant is then supplied to the refrigerant flow path 47 and further distributed to the refrigerant flow path 45 in each refrigerant discharge pipe 44.

  As shown in FIG. 2, the axis 44 a of each refrigerant discharge pipe 44 (refrigerant flow path 45) has an end on the rotor radial center side that coincides with the rotor radial direction, and from the rotor radial center to the rotor radial outer side. As it extends, it is inclined so as to be separated from the rotor radial direction in the rotor circumferential direction, and the end portion on the outer side in the rotor radial direction is parallel to the tangent line in the rotor circumferential direction. As a result, as shown by an arrow B in FIG. 2, a plurality of refrigerant discharge ports 48 (end portions on the outer side in the rotor radial direction of the refrigerant discharge pipes 44) arranged at regular intervals (equal intervals) in the circumferential direction of the rotor. From each of these, refrigerant oil is ejected in a direction parallel to the tangent line in the rotor circumferential direction. At that time, as the axis 44a of each refrigerant discharge pipe 44 extends from the rotor radial direction center side to the rotor radial direction outer side, the circumferential speed direction during rotor rotation with respect to the rotor radial direction (hereinafter referred to as rotor circumferential speed direction). Are inclined in the opposite direction so that the axis 44a of each refrigerant discharge port 48 is in the direction opposite to the rotor circumferential speed direction, so that any refrigerant oil is discharged from each refrigerant discharge port 48 in the direction opposite to the rotor circumferential speed direction. Is possible. Alternatively, the axis 44a of each refrigerant discharge pipe 44 is inclined in the rotor circumferential speed direction with respect to the rotor radial direction as the axis 44a extends from the rotor radial direction center side to the rotor radial direction outer side. By setting the circumferential speed direction, it is possible to discharge all the refrigerant oil from the refrigerant discharge ports 48 in the rotor circumferential speed direction. If the rotation direction of the rotor 14 is the direction indicated by the arrow D in FIG. 2, the circumferential speed direction during rotation of the rotor (rotor circumferential speed direction) is represented by the direction indicated by the arrow E in FIG.

  The refrigerant oil supplied to the refrigerant flow path 49 in the rotating shaft 13 by the discharge pressure of the oil pump 50 is supplied to the refrigerant flow path 51 in the rotor core 31, each refrigerant discharge hole 52 of the end plate 33, and the refrigerant distribution pipe 46. The stator 12 (stator coil 22) is supplied to the refrigerant flow path 45 of each refrigerant discharge pipe 44 through the refrigerant inlet 53 and the refrigerant flow path 47 and arranged on the outer peripheral side of each refrigerant discharge pipe 44 from each refrigerant discharge port 48. To the coil end portion 22a). By supplying refrigerant oil from each refrigerant discharge port 48 to the coil end portion 22a of the stator coil 22, the stator 12 (mainly the stator coil 22) can be cooled. Further, as shown by an arrow B in FIG. 2, the reaction force of the force in which refrigerant oil is ejected from each refrigerant discharge port 48 in a direction parallel to the tangent line in the rotor circumferential direction (rotor circumferential speed direction or the opposite direction) 2, the refrigerant discharge device 42 (each refrigerant discharge pipe 44 and the refrigerant distribution pipe 46) rotates relative to the rotating shaft 13 and the rotor 14 in the direction opposite to the refrigerant oil discharge direction. Thereby, even when the rotation of the rotor 14 is stopped (locked), the circumferential position of the stator coil 22 (coil end portion 22a) to which the refrigerant oil is supplied changes according to the rotation of the refrigerant discharge device 42. Therefore, the stator coil 22 (coil end portion 22a) can be uniformly cooled by the refrigerant oil. The oil pump 50 is, for example, a rotary electric machine so that the pressure of the refrigerant oil can be supplied to the refrigerant discharge device 42 and discharged from each refrigerant discharge port 48 even when the rotation of the rotor 14 is locked. Is rotated by a power source provided separately.

  Here, considering the case where the refrigerant oil passing through the refrigerant flow path 49 in the rotating shaft 13 is supplied to the stator 12 (coil end portion 22a) by the centrifugal force when the rotor rotates, for example, a high load is applied to the rotor 14 or the like. When the rotation of the rotor 14 is locked, the refrigerant oil is discharged only in a certain direction (vertically downward), and it becomes difficult to cool the stator 12 (coil end portion 22a) uniformly. On the other hand, in the present embodiment, while the refrigerant oil is supplied from each refrigerant discharge port 48 to the stator 12 (coil end portion 22a), the reaction of the jet output of the refrigerant oil from each refrigerant discharge port 48 is used. Thus, the refrigerant discharge device 42 can be rotated relative to the rotating shaft 13 and the rotor 14 in the direction opposite to the direction in which the refrigerant oil is ejected. Therefore, for example, even when the rotor 14 is locked due to a heavy load applied to the rotor 14, the refrigerant discharge device 42 determines the circumferential position of the stator 12 (coil end portion 22 a) where the refrigerant oil is supplied. The refrigerant oil can be uniformly supplied over the entire circumference of the stator 12 (coil end portion 22a), so that the stator 12 (coil end portion 22a) can be made uniform by the refrigerant oil. Can be cooled. As a result, the cooling performance of the stator 12 (coil end portion 22a) can be improved, and the temperature variation of the stator 12 (coil end portion 22a) can be reduced. For example, when a rotating electrical machine is used as a power source for a vehicle, the stator 12 (coil end portion 22a) is uniformly cooled with refrigerant oil even when the rotation of the rotor 14 is locked on a steep slope. Can do.

  In the above description of the embodiment, the axis 44a of the refrigerant discharge port 48 is parallel to the tangent in the rotor circumferential direction, and refrigerant oil is discharged from the refrigerant discharge port 48 in a direction parallel to the tangent in the rotor circumferential direction. . However, in the present embodiment, the axis 44a of the refrigerant discharge port 48 is set within a range in which the condition that the flow velocity of the refrigerant oil discharged from the refrigerant discharge port 48 has a speed component in a direction parallel to the tangential line in the rotor circumferential direction is satisfied. It is also possible to discharge the refrigerant oil from the refrigerant discharge port 48 in a direction inclined with respect to the tangent in the rotor circumferential direction with an inclination with respect to the tangent in the rotor circumferential direction. Even in this case, the refrigerant discharge device 42 is used by utilizing the reaction of the refrigerant oil jet output from the refrigerant discharge port 48 while supplying the refrigerant oil from the refrigerant discharge port 48 to the stator 12 (coil end portion 22a). The rotating shaft 13 and the rotor 14 can be rotated relative to each other. At that time, the axis 44a of each refrigerant discharge port 48 is set within a range where the condition that the flow velocity of the refrigerant oil discharged from each refrigerant discharge port 48 has a speed component in the direction opposite to the rotor circumferential speed direction is satisfied. It is possible to discharge the refrigerant oil from each refrigerant discharge port 48 in a direction inclined with respect to the direction opposite to the rotor circumferential speed direction by being inclined with respect to the direction opposite to the rotor circumferential speed direction. Alternatively, the axis 44a of each refrigerant discharge port 48 is set to the rotor circumferential speed direction within a range where the condition that the flow rate of the refrigerant oil discharged from each refrigerant discharge port 48 has a speed component in the rotor circumferential speed direction is satisfied. It is also possible to discharge the refrigerant oil from each refrigerant discharge port 48 in a direction inclined with respect to the rotor circumferential speed direction. However, in order to efficiently rotate the refrigerant discharge device 42 relative to the rotary shaft 13 and the rotor 14 by using the reaction of the jetting output of the refrigerant oil from the refrigerant discharge port 48, the discharge from the refrigerant discharge port 48 is performed. The flow rate of the refrigerant oil is preferably dominated by the speed component in the direction parallel to the tangent line in the rotor circumferential direction (rotor circumferential speed direction or the opposite direction). It is preferably sufficiently larger than the velocity component.

  As mentioned above, although the form for implementing this invention was demonstrated, this invention is not limited to such embodiment at all, and it can implement with a various form in the range which does not deviate from the summary of this invention. Of course.

  12 Stator, 13 Rotating shaft, 14 Rotor, 21 Stator core, 22 Stator coil, 22a Coil end part, 23 Teeth, 31 Rotor core, 32 Permanent magnet, 33 End plate, 41 Bearing, 42 Refrigerant discharge device, 44 Refrigerant discharge pipe, 45 , 47, 49, 51 Refrigerant flow path, 46 Refrigerant distribution pipe, 48 Refrigerant outlet, 50 Oil pump, 52 Refrigerant outlet, 53 Refrigerant inlet, 54, 56 Seal ring.

Claims (4)

A rotor that rotates with the rotating shaft;
A stator disposed opposite to the rotor on the outer peripheral side of the rotor;
A refrigerant discharge device that has a refrigerant discharge port for discharging the refrigerant supplied from the refrigerant flow path formed on the rotation shaft toward the stator, and is rotatable relative to the rotation shaft and the rotor;
With
The refrigerant discharge device discharges the refrigerant from the refrigerant discharge port so that the flow velocity of the refrigerant discharged from the refrigerant discharge port has a velocity component in a direction parallel to the tangent in the circumferential direction of the rotor. A rotating electric machine that rotates. The rotating electrical machine according to claim 1,
The refrigerant discharge device is a rotating electrical machine that rotates relative to the rotation shaft and the rotor by discharging refrigerant from a refrigerant discharge port in a direction parallel to a tangent line in the circumferential direction of the rotor. The rotating electrical machine according to claim 1 or 2,
The refrigerant discharge device has a plurality of refrigerant discharge ports,
A plurality of refrigerant discharge ports are arranged at intervals from each other in the circumferential direction of the rotor,
In the refrigerant discharge device, the flow velocity of the refrigerant discharged from each refrigerant discharge port has a speed component in the rotor circumferential speed direction, or the flow velocity of the refrigerant discharged from each refrigerant discharge port is in the direction opposite to the rotor circumferential speed direction. A rotating electrical machine that rotates relative to a rotating shaft and a rotor by discharging refrigerant from each refrigerant discharge port so as to have a speed component. The rotating electrical machine according to any one of claims 1 to 3,
The refrigerant discharge device is a rotating electrical machine that is rotatably supported by a rotating shaft at an outer end in a rotating shaft direction of the rotor.

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