DE112018002784T5 - Rotary electric machine for an internal combustion engine - Google Patents

Abstract

The rotary electric machine (10) has a rotor (21) and a stator (31). The rotor has a nozzle (51) for generating an oil jet (61). A central axis (56) of the nozzle is directed towards an exposed core section of the stator core (32). As a result, the beam does not directly hit the stator coil (33). Damage to the resin covering the stator coil is suppressed. The central axis of the nozzle extends without cutting the rotor core (22) on the radially outer side and the radially inner side of the nozzle. Such an arrangement of the central axis simplifies an arrangement of the machining tools and increases a degree of freedom in the selection of the machining tools in a process of machining a large-diameter hole (54) and a small-diameter hole (55).

Description

[CROSS REFERENCE TO RELATED APPLICATION]

The present application claims priority from Japanese patent application number 2017-107745 , filed in Japan, filed on May 31, 2017, the entire disclosure of the aforementioned application being incorporated herein by reference.

TECHNICAL AREA

The disclosure in this specification relates to a rotary electric machine for an internal combustion engine.

STATE OF THE ART

Patent Literature 1 discloses a rotary electric machine for an internal combustion engine. The prior art produces an oil jet that is injected from a rotating shaft. The oil jet is aimed at one end of the spool and collides directly with the end of the spool.

[PRIOR ART LITERATURE]

[PATENT LITERATURE]

[PATENT LITERATURE 1] JP 2013-9508A

SUMMARY OF THE INVENTION

[TECHNICAL TASK]

The coil end is a bundle of a variety of wires. The coil end is secured and protected by being coated with an electrically insulating resin such as epoxy or top coat. However, in the configuration of the prior art, the resin may be damaged by, for example, a jet of a cooling liquid, such as an oil, or a foreign substance contained in the cooling liquid. In addition, if this is significant, the resin may peel off. This resin damage affects the durability of the rotary electric machine for the internal combustion engine.

In the aforementioned aspects or other aspects not mentioned, there is a need for further improvements of a rotary electric machine for an internal combustion engine.

It is an object of the disclosure to provide an oil-cooled rotary electric machine for an internal combustion engine that has high durability.

It is another object of the disclosure to provide a rotary electric machine for an internal combustion engine that can cool a coil while protecting the coil.

It is still another object of the disclosure to provide a rotary electric machine for an internal combustion engine that can cool the entire stator while suppressing mechanical damage to the resin of the coil.

[SOLUTION TO THE TASK]

A rotary electric machine for an internal combustion engine in the disclosure has: a rotor core ( 22 ) with permanent magnets ( 23 ) which are arranged on an inner surface; a stator core ( 32 ) arranged radially inward of the rotor core; and a stator coil ( 33 ) attached to part of the stator core and sealed with a resin ( 34 ) is protected, the rotor core being a nozzle ( 51 ) which is formed in the rotor core and has a beam ( 61 ) forms a coolant and is directed to the stator core without being directed to the stator coil.

According to a disclosed rotary electric machine for an internal combustion engine, a coolant is injected through the nozzle. The nozzle is directed at the stator core without being directed at the stator coil. For this reason, the jet formed by the nozzle hits the stator core directly without directly hitting the stator coil protected by the resin. For this reason, damage to the resin due to the cooling liquid or foreign matter contained in the cooling liquid is suppressed. The coolant cools the stator core and the stator coil. For this reason, a rotary electric machine with high durability is provided.

The aspects disclosed in this description use different technical solutions from each other in order to achieve their respective goals. Reference numerals in parentheses, which are described in the claims and in this section, show, by way of example, corresponding relationships with parts of the exemplary embodiments described later, and are not intended to restrict technical scope. The objects, features and advantages disclosed in this description will become apparent by reference to the following detailed descriptions and accompanying drawings.

Figure list

• 1 is a schematic sectional view of a rotary electric machine according to a first embodiment.
• 2nd is a schematic sectional view of a stator coil.
• 3rd Fig. 14 is a sectional perspective view showing a detailed form of the rotary electric machine.
• 4th 12 is a sectional perspective view showing a detailed form of a rotary electric machine according to a second embodiment.

DESCRIPTION OF THE EXEMPLARY EMBODIMENTS

A number of exemplary embodiments are described below with reference to the drawings. In some exemplary embodiments, parts that correspond functionally and / or structurally to one another and / or are related to one another are provided with the same reference symbols, or with reference symbols with different hundreds or more digits. For corresponding parts and / or related parts, reference can be made to the description of the other exemplary embodiments.

First embodiment

In 1 is a rotary electric machine for an internal combustion engine (hereinafter simply referred to as a rotary electric machine 10th a generator. The rotary electric machine 10th can be used for a vehicle, a ship or an aircraft. The rotary electric machine 10th can be used for a ride-on vehicle.

The rotary electric machine 10th is on the internal combustion engine 12th assembled. The internal combustion engine 12th has a body 13 and a rotating shaft 14 by the body 13 rotatably supported and in connection with the internal combustion engine 12th is rotatable. The body 13 is a structure such as a crankcase or a transmission case of the internal combustion engine 12th . The body 13 defines a cavity 13a , in which the oil for lubricating the internal combustion engine 12th can be present. The oil serves as a coolant for the rotary electric machine 10th . The oil also has a function of setting a temperature of the internal combustion engine 12th . For example, the body defines 13 the cavity 13a between a main housing and a cover of the internal combustion engine 12th . The rotary electric machine 10th is in the cavity 13a housed.

The rotary electric machine 10th is on the body 13 and the rotating shaft 14 assembled. The rotating shaft 14 is a crankshaft of the internal combustion engine 12th or a rotating shaft that is synchronous with the crankshaft. The rotating shaft 14 can turn when the internal combustion engine 12th is operated. The rotating shaft 14 drives the rotary electric machine 10th to serve as the generator.

The rotary electric machine 10th is a rotary electric machine of the outer rotor type. It has a rotor 21 and a stator 31 . In the following description, the term "axial direction" refers to a direction along a central axis when the rotor 21 , the stator 31 or the stator core 32 can be considered as a cylinder. In the following description, the term "radial direction" refers to a radial direction when the rotor 21 , the stator 31 or the stator core 32 can be considered as a cylinder.

The rotor 21 is a field element. The rotor 21 is overall pot-shaped. The rotor 21 is at the end portion of the rotating shaft 14 attached. The rotating shaft 14 has an outer surface 14a to hold the rotor 21 . The outside surface 14a is a tapered surface that tapers. The rotor 21 and the rotating shaft 14 are connected via a positioning mechanism such as a key in one direction of rotation. The rotor 21 is through a mother 14b , which is a fastening component, is fastened and fixed to the rotary shaft. The rotor 21 rotates together with the rotating shaft 14 . The rotor 21 provides the field with a permanent magnet.

The rotor 21 has a pot-shaped rotor core 22 . The rotor core 22 is with the rotating shaft 14 of the internal combustion engine 12th connected. The rotor core 22 provides a yoke for a permanent magnet, which will be described later. The rotor core 22 is made of a magnetic metal. The rotor 21 has a permanent magnet 23 that is on an inner surface of the rotor core 22 is arranged.

The rotor core 22 has an inner cylinder 22a , an outer cylinder 22b and a bottom plate 22c . The inner cylinder 22a is with the rotating shaft 14 connected. The inner cylinder 22a provides a hub section. The outer cylinder 22b is on a radially outer side of the inner cylinder 22a and away from the inner cylinder 22a located. The outer cylinder 22b carries the permanent magnets 23 on the inner surface. The bottom plate 22c is an annular plate. The bottom plate 22c extends between the inner cylinder 22a and the outer cylinder 22b .

The inner cylinder 22a has a through hole that the rotary shaft 14 records. The inner cylinder 22a has an inner surface 22d . The inner surface 22d is a beveled surface that is the outer surface 14a contacted. A transition area 22e that the outer surface of the inner tube 22a and the inner surface of the bottom plate 22c connects seamlessly, is between the inner tube 22a and the bottom plate 22c provided. The transition area 22e is a surface whose diameter is from the inner cylinder 22a towards the bottom plate 22c gradually increases. The transition area 22e is formed by a concave curved surface. The inner cylinder 22a , the outer cylinder 22b and the bottom plate 22c are made of a continuous material.

The stator 31 is an anchor element. The stator 31 is an annular component. The stator 31 is an outer stator of the salient pole type. The stator 31 is on the body 13 fixed. The stator 31 has a through hole that the rotary shaft 14 and the inner cylinder 22a can record. The stator 31 has an outer peripheral surface that is the inner surface of the rotor 21 across a gap.

The stator 31 has a stator core 32 . The stator core 32 is inside the rotor 21 arranged. The stator core 32 is on the body 13 of the internal combustion engine 12th fixed. A form of the stator core 32 is characterized by an annular portion provided on a radially inner side and a plurality of teeth (salient poles) provided on a radially outer side.

The stator 31 has a stator coil 33 working on a stator core 32 is appropriate. The stator coil 33 is on part of the stator core 32 appropriate. The stator coil 33 is around the stator core 32 wrapped. The stator coil 33 is a multi-phase winding. The stator coil 33 is on the radially outer teeth of the stator core 32 arranged. The stator coil 33 provides an armature winding. The stator core 32 is on the body 13 through bolts 35 fixed, the fastening components are. The bolt 35 goes through the stator core 32 through it. The bolt 35 fixes the stator core 32 on a cover of the body 13 . The bolt 35 can be part of the rotary electric machine 10th or part of the internal combustion engine 12th to be viewed as.

The internal combustion engine 12th has a supply device 41 to supply the cavity 13a with the oil. The supply device 41 has an oil pan 43 that stores the oil, and an oil pump 42 . The supply device 41 has a circulation path through the cavity 13a goes through. The circulation path has an axial passage 14c that in the rotating shaft 14 is provided. The axial passage 14c extends parallel to the central axis of the rotating shaft 14 . Furthermore, the circulation passage has a radial passage 14d that in the rotating shaft 14 is provided.

The radial passage 14d is with respect to the central axis of the rotating shaft 14 inclined. The radial passage 14d opens to the outside surface 14a and the axial passage 14c . The radial passage 14d opens to the axial passage 14c at one end on the radially inner side. The radial passage 14d opens to the outside surface 14a at the other end on the radially outer side. The radial passage 14d is in fluid communication with the outer surface 14a the rotating shaft 14 and the inside of the axial passage 14c . The axial passage 14c and the radial passage 14d are passages that the oil used to cool the rotary electric machine 10th respectively.

The rotor 21 has a nozzle 51 . The nozzle 51 is also part of the circulation cycle. The nozzle 51 has a straight shape to an oil jet 61 to build. The nozzle 51 is in the rotor core 22 educated. The nozzle 51 is at a connecting portion between the inner cylinder 22a and the bottom plate 22c provided. The nozzle 51 opens on the inside surface 22d and the transition surface 22e . The nozzle 51 is to the inner surface 22d open at one end on the radially inner side. The nozzle 51 is to the transition surface 22e open at the other end on the radially outer side. The nozzle 51 extends in the radial direction. The nozzle 51 connects the inner surface 22d and the transition surface 22e through the rotor core 22 .

An opening of the radial passage 14d in the outer surface 14a and an opening of the nozzle 51 in the inner surface 22d are in fluid communication. The nozzle 51 takes the oil from the radial passage 14d and injects it outward in the radial direction. The nozzle is a passage that is the oil for cooling the rotary electric machine 10th feeds.

A position of the opening of the radial passage 14d in the outer surface 14a and a position of the opening of the nozzle 51 in the inner surface 22d match each other in the circumferential direction and the axial direction so that the oil flows. There may be circumferential grooves and / or axial grooves on the outer surface 14a and / or the inner surface 22d give a connection between the radial passage 14d and the nozzle 51 to provide.

The central axis of the nozzle 51 is with respect to the central axis of the rotating shaft 14 inclined. The nozzle 51 is inclined so that it extends outward in the radial direction from the engine side of the rotating shaft 14 , that is, from the bottom end side toward the distal end side of the rotating shaft 14 extends. The nozzle 51 is inclined so that it faces a narrow cavity that is between the rotor 21 and the stator 3rd is trained. The nozzle 51 is on an extension of the radial passage 14d located. A central axis of the nozzle 51 coincides with a central axis of the radial passage 14d match.

The oil is in the oil pan 43 saved. The oil is pumped through the oil pump 42 from the oil pan 43 sucked in. The oil pump 42 circulates the oil through the circulation path. The oil becomes the axial passage 14c fed. The oil passes from the axial passage 14c to the radial passage 14d fed. The oil is from the radial passage 14d to the nozzle 51 fed. The oil comes from the nozzle 51 injected to a jet 61 to build. The oil sets the temperature of the rotary electric machine 10th on. In many cases, the oil cools the rotary electric machine 10th . The oil returns from the cavity 13a back to the oil pan 43 back. It should be noted that the circulation path can contain an oil cooler. The circulation path can contain a sieve that collects foreign matter.

The nozzle 51 is on the stator core 32 directed without on the stator coil 33 to be judged. The nozzle 51 forms an oil jet 61 . Hence the beam 61 also on the stator core 32 directed without on the stator coil 33 to be judged. The beam 61 has a central axis through the nozzle 51 is defined. The central axis of the beam 61 agrees with the mechanical center axis of the nozzle 51 match. The beam 61 extends from the transition surface 22e towards the radially outer side.

The beam 61 is on an annular portion on the radially inner side of the stator 31 directed. The beam 61 is not on an annular portion on the radially outer side of the stator 31 directed. The beam 61 is on an end face of the stator core 32 directed. The beam 61 is on an exposed portion of the stator core 32 directed. The beam 61 is directed to the stator coil 33 avoids. The beam 61 does not directly hit the stator coil 33 . The beam 61 extends outward in the radial direction. The beam 61 is from a corner between the inner cylinder 22a and the bottom plate 22c of the rotor 21 towards an opening of the rotor 21 inclined.

2nd is a sectional view showing the stator coil 33 shows in a schematic manner. The coil wire 33a which is the stator coil 33 has a single wire line 33b and a resin 33c that the line 33b covers. The coil wire 33a can be provided by a plurality of lines, for example two. The administration 33b is made of a copper-based metal such as copper or a copper alloy. The administration 33b can be made of an aluminum-based metal such as aluminum or an aluminum alloy. Therefore, the coil wire 33a which is the stator coil 33 forms through the resin 33c protected.

Furthermore, the stator coil 33 as a bundle of coil wires 33a with a resin 33d , for example coating varnish or epoxy. The sink 33 is through the resin 33d fixed. The resin 33d fixes a large number of adjacent coil wires 33a and / or coil wires 33a and other components. The resin 33d fixes the coil wire 33a to a core, teeth, an insulating member called a bobbin, an insulating layer attached to the core surface. Therefore, the stator coil 33 through the resin 33d protected.

In this description both the resin 33c that the coil wire 33a covers, as well as the resin 33d that the stator coil 33 covers as a resin 34 to protect the stator coil 33 designated. The resin 34 has an insulating property. According to this embodiment, damage to the resin 34 suppressed, which is caused by oil or a foreign substance contained in the oil.

3rd shows a concrete form of the rotary electric machine 10th . The stator core 32 is on the body 13 through a variety of bolts 35 fixed. The variety of bolts 35 are in the radially inner portion of the stator core 32 arranged, that is, in an annular exposed portion. The bolt 35 has a head section 35a . A variety of minds 35a are on the annular exposed portion of the stator core 32 located. The multitude of heads 35a are arranged on a circular path. The head section 35a is between the stator core 32 and the bottom plate 22c located.

The variety of bolts 35 are received in through holes in the stator core 32 are trained. The stator core 32 has a first end plate 32a , a core section 32b and a second end plate 32c . The first end plate 32a , the core section 32b and the second end plate 32c are made of electromagnetic steel plates. The core section 32b is a laminate in which a variety of electromagnetic steel plates are laminated. The first end plate 32a and the second end plate 32c can be magnetic metal plates.

The stator 31 has an insulating part 36 . The insulating part 36 is made of an electrically insulating resin. The insulating part 36 is between the stator core 32 and the stator coil 33 arranged. Part of the insulating part 36 extends over the stator core 32 . The stator coil 33 is with the resin 34 on the insulating part 36 covered.

The nozzle 51 has an inlet 52 that on the inner surface 22d is located, and an outlet 53 that on the transition surface 22e is located. A cross-sectional area of the inlet 52 is larger than a cross-sectional area of the outlet 53 . The nozzle 51 has a large diameter hole 54 and a small diameter hole 55 .

The large diameter hole 54 represents the entrance 52 ready. The large diameter hole 54 has a predetermined inner diameter. The large diameter hole 54 extends from the inner surface 22d in the inner cylinder 22a . The large diameter hole 54 ends in the inner cylinder 22a . The large diameter hole 54 is a cylindrical hole machined by a drill.

The small diameter hole 55 opens on a wall surface of the large diameter hole 54 . The small diameter hole 55 is behind the large diameter hole 54 arranged along the oil flow direction. The small diameter hole 55 has an inner diameter that is smaller than the large diameter hole 54 . The small diameter hole 55 is designed to match the shape of the beam 61 Are defined. The small diameter hole 55 extends from the end of the large diameter hole 54 in the inner cylinder 22a . The small diameter hole 55 opens on the transition area 22e . The outlet 53 is through the small diameter hole 55 provided. The small diameter hole 55 provides fluid communication between an interior of the large diameter hole 54 and the transition surface 22e ready. The small diameter hole 54 is a cylindrical hole machined by a drill. The small diameter hole 55 is on the stator core 32 directed without on the stator coil 33 to be judged.

The large diameter hole 54 and the small diameter hole 55 have a common central axis 56 . The central axis of the large diameter hole 54 and the central axis of the small diameter hole 55 can be arranged away from each other and in parallel. Furthermore, the central axis of the large diameter hole 54 and the central axis of the small diameter hole 55 intersect each other.

It can be assumed that the central axis of the large diameter hole 54 and the central axis of the small diameter hole 55 from the nozzle 51 extend towards the radially outer side and the radially inner side. The central axis 56 cuts the rotor 21 on the radially outer side and the radially inner side of the nozzle 51 Not. The central axis 56 extends from an open end of the rotor 21 , that is, an opening opposite the base plate 22c , on the radially outer side. The central axis 56 extends from an opening of the through hole that the inner surface 22d forms on the radially inner side. In other words, the nozzle 51 the central axis 56 that the rotor core 22 on the radially inner side of the nozzle 51 does not cut. The nozzle 51 has the central axis 56 that the rotor core 22 on the radially outer side of the nozzle 51 does not cut. Such an arrangement of the central axis of the large diameter hole 54 and the central axis of the small diameter hole 55 simplifies the arrangement of the machining tools and increases the degree of freedom in the selection of the machining tools in a machining process of the nozzle 51 .

The central axis 56 extends outward from the rotor 21 without the inside surface 22d to cut. In other words, the inlet 52 from the rear end face of the rotor 21 along the central axis 56 be seen directly. In the manufacturing process, the machining tool can be the inlet 52 along the central axis 56 to reach.

If there is no stator core 32 there intersects the central axis 56 of the small diameter hole 55 the rotor core 22 not, for example the outer cylinder 22b , on the radially outer side. The central axis 56 of the small diameter hole 55 extends towards the open end of the rotor 21 . In the manufacturing process, the machining tool can have the outlet 53 along the central axis 56 to reach.

In a state in which the rotary electric machine 10th on the internal combustion engine 12th is assembled (hereinafter referred to as a regular assembly state), the rotor 21 under stator 31 fixed in the state shown. That is, the stator 31 is in the rotor 21 arranged. In this state, the rotating shaft rotates 14 , and the rotor 21 turns. At the same time, the oil from the supply device 41 fed. The oil flows through the nozzle 51 along the central axis 56 . The oil is at the outlet 53 to a ray. The beam 61 flows towards the radially outer side. The beam 61 is mainly through the small diameter hole 55 educated. A diameter of the beam 61 , for example a diameter at a position when the stator core is reached 32 depends on the diameter of the small diameter hole 55 from. An angle of divergence of the beam 61 depends on the diameter and length of the small diameter hole 55 from. It also affects roughness of the inner surface of the small diameter hole 55 and / or a chamfer formed on the outlet also the shape of the beam 61 .

In the case of the in 3rd shown rotor 21 is the exit 53 of the small diameter hole 55 on the transition area 22e provided which is a concave curved surface. If a chamfer on the outlet 53 trained is the Chamfer on the core side (left side in the figure) larger than the rotor bottom surface side. The injected oil is drawn by the surface effect of the chamfer. As a result, the injected oil is not applied to the radially inner portion of the stator core 32 directed, and the direct meeting of the stator coil 33 is suppressed.

The beam 61 turns with a rotation of the rotor 21 . The beam 61 hits the stator 31 . The oil comes with the rotation of the jet 61 the entire stator 31 fed. The beam 61 moves along a circular path 62 while the stator core 32 meets. The beam 61 hits the head 35a . The beam 61 intermittently crosses the multitude of heads 35a while moving along the circular path 62 emotional. The oil that the stator 31 has reached the temperature of the stator 31 and flows into the cavity 13a down.

The central axis 56 is also a central axis of the beam 61 . The central axis 56 cuts the stator core 32 . In other words, the central axis intersects 56 the radially inner portion of the stator core 32 . In other words, the central axis intersects 56 an annular exposed portion of the stator core 32 . The central axis 56 does not cut the stator coil 33 .

The nozzle is in the normal assembly state 51 on the stator core 32 directed. More specifically, the nozzle is 51 directed to a section where the stator core 32 in the radially inner portion of the stator core 32 is exposed, that is, subsequently, an exposed core section. The nozzle 51 is not on the stator coil 33 directed. In another aspect, the stator core 32 an annular exposed core section where the stator core 32 is exposed without passing through the stator coil 33 to be covered. The nozzle 51 is aimed at the exposed core section. In another aspect, the stator core 32 an annular portion provided on the radially inner side and a plurality of teeth provided on the radially outer side. The stator coil 33 is attached to the variety of teeth. The nozzle 51 is directed towards the annular section.

In another aspect it can be said that the nozzle 51 on the circular path 62 is directed where the heads 35a the variety of bolts 35 are installed. In other words, the central axis 56 of the small diameter hole 55 directed in the direction of the exposed core section in the direction of the radially outer side. The central axis 56 of the small diameter hole 55 is set to be the stator coil 33 not reached. The circular path 62 is also a cutting path of the stator core 32 and the central axis 56 . As a result, the beam hits 61 the stator core 32 directly and then flows towards the stator coil 33 .

The manufacturing process of the rotary electric machine 10th involves a manufacturing process of the rotor 21 , a manufacturing process of the stator 31 and a process of combining the rotor 21 and the stator 31 than the rotary electric machine 10th on the internal combustion engine 12th . The manufacturing process of the rotor 21 involves a process of machining a metal material around the rotor core 22 form, and a process of attaching a permanent magnet 23 on the machined rotor core 22 . The process of machining the rotor core 22 includes a basic process of forming a pot-like shape with the inner cylinder 22a , the outer cylinder 22b and the bottom plate 22c . The machining process also includes the rotor core 22 a nozzle machining process for the nozzle 51 which is carried out in the middle of the basic process or after the basic process.

The nozzle machining process includes a large-diameter hole process for machining the large-diameter hole 54 and a small diameter hole process for machining the small diameter hole 55 . Either the large-diameter hole process or the small-diameter hole process can be carried out first. In the large-diameter hole process, the large-diameter hole becomes 54 by applying the processing tool to the inner surface 22b educated. For example, the large diameter hole 54 through a drill from the inner surface 22d educated. Because the central axis 56 the rotor core 22 does not cut, the large diameter hole 54 machined while interacting between the machining tool and the rotor core 22 is suppressed. In the small diameter hole process, the machining tool is placed on the transition surface 22e applied, and the small diameter hole 55 is being trained. For example, the small diameter hole 55 through a drill from the transition surface 22e educated. Because the central axis 56 the rotor core 22 does not cut, the small diameter hole 55 machined while interacting between the machining tool and the rotor core 22 is suppressed. In particular, a chuck device can be close to an environment of the large diameter hole 54 and / or the small diameter hole 55 to be brought. As a result, a thick machining tool can be used, and malfunctions such as breakage or deformation of a drill can be suppressed.

In the large diameter punching process, the processing tool can be on the inner surface 22d from the large diameter side of the through hole that is applied to the inner surface 22d forms. Because of this, the contact angle between the inner surface 22d and the machining tool are close to a right angle. Therefore, an initial cutting of the machining tool with respect to the inner surface 22d be improved.

In the small-diameter hole process, the machining tool can be on the transition surface 22e from the open end of the rotor core 22 be applied. For this reason, the contact angle between the transition surface 22e and the machining tool are close to a right angle. Therefore, an initial cutting of the machining tool with respect to the inner surface 22d be improved.

In this embodiment, the beam hits 61 directly the exposed core section of the stator core 32 . The beam 61 does not directly hit the stator coil 33 . This causes the breakage of the resin caused by the oil or a foreign substance contained in the oil 34 suppresses that the stator coil 33 covers. In particular, the resin takes 34 a heavy load because of the small diameter hole 55 the pulse of the beam 61 elevated. Even in this case, breakage of the resin is suppressed. Because the break of the resin 34 the durability of the rotary electric machine 10th is reduced, according to this embodiment, the rotary electric machine 10th provided with high durability. For example, it allows the resin to break 34 the coil wire to move, and therefore can cause the coil to disconnect or short-circuit. Damage to the resin 34 can cause foreign substances to be mixed into the injected oil. Therefore, there is a risk of causing problems in the internal combustion engine and the lubrication path, such as the strainer. This embodiment suppresses such an undesirable defect.

Second embodiment

This embodiment is a modified example based on the aforementioned embodiment. In the aforementioned embodiment, the direct collision between the stator coil 33 and the beam 61 exclusively by the direction of the nozzle 51 suppressed. In this embodiment, the insulating part 36 a protective wall 236a .

The bulkhead 236a is also called a barrier section or a barrier wall. The bulkhead 236a extends along the radially inner side of the stator coil 33 . The bulkhead 236a has a cylindrical shape. The bulkhead 236a is between the annular portion of the stator core 32 and the plurality of teeth. The bulkhead 236a is vertically arranged on a plate-like portion which is the annular portion of the stator core 32 in the insulating part 36 covers. The bulkhead 236a extends from the end face of the stator core 32 in the axial calculation. The bulkhead 236a covers the radially inner surface of the stator coil 33 within a predetermined range from the stator core 32 in the axial direction. The bulkhead 236a is not so high that it covers the entire radially inner surface of the stator coil 33 covers.

The bulkhead 236a the oil prevents the stator coil 33 to meet directly. The bulkhead 236a prevents a lot of the beam 61 or a temporarily rebounding flow of the jet 61 remember the stator coil 33 to meet directly. The bulkhead 236a improves a degree of freedom in correcting conditions such as the oil flow rate and the directional direction of the jet 61 in a direction that improves cooling performance while making a direct collision of the beam 61 on the stator coil 33 suppressed.

Other embodiments

The disclosure in this description is not restricted to the exemplary embodiment shown. The disclosure includes the illustrated embodiments and modifications based on them by those skilled in the art. For example, the disclosure is not limited to the parts and / or combinations of the elements shown in the exemplary embodiments. The disclosure can be implemented in various combinations. The disclosure may have additional parts that can be added to the embodiment. The disclosure includes omitting parts and / or elements of the exemplary embodiments. The disclosure includes replacing or combining parts and / or elements between one embodiment and another. The technical scope disclosed is not limited to the description of the exemplary embodiment. Several disclosed technical scopes are indicated by descriptions in the claims, and should be understood to include all modifications within the meaning and scope that are equivalent to the descriptions in the claims.

In the aforementioned embodiment, the coolant is provided by oil. If the internal combustion engine 12th is water-cooled, the coolant can alternatively be provided by water for water cooling.

In the aforementioned embodiment, the rotary electric machine 10th with the vehicle internal combustion engine 12th connected. Alternatively, the rotary electric machine 10th can be used for a generator of the stationary type or the portable type.

In the aforementioned embodiment, the rotary electric machine 10th the generator ready. Alternatively, the rotary electric machine 10th provide a motor generator or an alternating current starter generator. Alternatively, the rotary electric machine 10th a rotational position sensor for detecting the rotational position of the rotor. The rotational position sensor detects a special magnetic pole of the rotor or a magnetic pole of a permanent magnet. The rotational position sensor is provided between the stator and the body. The rotary position sensor is arranged so that the oil mist is not applied directly. For example, the oil injection connection (outlet 53 ) is preferably arranged on the end surface opposite the end surface on which the rotational position sensor on the stator 31 is installed. In this case, the rotary electric machine 10th electrically connected to an electrical circuit having an inverter circuit and a control device. The control device controls the electrical power, that of the rotary electric machine 10th is fed so that the rotary electric machine 10th serves as an electric motor by controlling the inverter circuit according to the rotational position detected by the rotational position sensor.

In the aforementioned embodiment, the transition surface 22e provided by a concave curved surface. Alternatively, the transition area 22e be a bevel. The inner cylinder is even on the slope 22a and the bottom plate 22c seamlessly connected.

In the above embodiment, there is a nozzle 51 provided. Alternatively, a variety of nozzles 51 be provided. The number of nozzles 51 is set according to a required amount of oil.

Reference list

10 rotary electric machine, 12 internal combustion engine, 13 body, 13a cavity, 14 rotary shaft, 14a outer surface, 14b nut, 14c axial passage, 14d radial passage, 21 rotor, 22 rotor core, 23 permanent magnet, 31 stator, 32 stator core, 33 stator coil, 33c, 33d, 34 resin, 35 bolts, 35a head, 36 insulating part, 41 supply device, 42 oil pump, 43 oil pan, 51 nozzle, 52 inlet, 53 outlet, 54 large diameter hole, 55 small diameter hole, 56 central axis, 61 jet, 62 circular path.

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• JP 2017107745 [0001]
• JP 2013009508 A [0004]

Claims (10)

Rotary electric machine for an internal combustion engine with: a rotor core (22) with permanent magnets (23) arranged on an inner surface; a stator core (32) disposed radially inward of the rotor core; and a stator coil (33) attached to a part of the stator core and protected by a resin (34), wherein the rotor core has a nozzle (51) which is formed in the rotor core and forms a jet (61) of a cooling liquid and which is directed onto the stator core without being directed towards the stator coil. Rotary electric machine for an internal combustion engine Claim 1 wherein the stator core has an annular exposed core portion where the stator core is exposed without being covered by the stator coil, and the nozzle is directed toward the exposed core portion. Rotary electric machine for an internal combustion engine Claim 1 or 2nd , wherein the stator core has an annular portion provided on a radially inner side and a plurality of teeth provided on a radially outer side, and wherein the stator coil is attached to the plurality of teeth, and wherein the nozzle is on the annular portion is directed. Rotary electric machine for an internal combustion engine according to one of the Claims 1 to 3rd wherein the nozzle has a large-diameter hole (54) with a predetermined inner diameter, and a small-diameter hole (55) which is arranged after the large-diameter hole along a flow direction of the cooling liquid and which has an inner diameter which is smaller than the large-diameter hole. Rotary electric machine for an internal combustion engine Claim 4 , wherein the small diameter hole is directed to the stator core without being directed to the stator coil. Rotary electric machine for an internal combustion engine Claim 4 or 5 , the small diameter hole being formed to define a shape of the beam. Rotary electric machine for an internal combustion engine according to one of the Claims 4 to 6 , the large diameter hole and the small diameter hole having a common central axis (56). Rotary electric machine for an internal combustion engine according to one of the Claims 1 to 7 wherein the nozzle has a central axis (56) that does not intersect the rotor core on a radially inner side of the nozzle. Rotary electric machine for an internal combustion engine according to one of the Claims 1 to 8th wherein the nozzle has a central axis (56) that does not intersect the rotor core on a radially outer side of the nozzle. Rotary electric machine for an internal combustion engine according to one of the Claims 1 to 9 wherein the rotor core has: an inner cylinder (22a) coupled to the rotary shaft (41) of the internal combustion engine; an outer cylinder (22b) carrying a permanent magnet on an inner surface; and a bottom plate (22c) extending between the inner cylinder and the outer cylinder, the inner cylinder having: an inner surface (22d); and a transition surface configured to seamlessly connect the inner cylinder and the bottom plate between the inner cylinder and the bottom plate, and wherein the nozzle connects the inner surface and the transition surface through the rotor core.

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