DE102017210778A1 - Electric machine, in particular for a vehicle - Google Patents

Abstract

Electric machine (1), in particular for a vehicle, - with a rotor (3) which is rotatable about a rotation axis (D), by which an axial direction (A) of the electric machine (1) is defined, and with a stator (2) having stator windings (6), - with a coolant distribution chamber (4) and an axially spaced therefrom coolant collecting chamber (5), wherein the coolant distribution chamber (5) for cooling the stator windings (6) by means of at least one of a coolant (K) through-flowable cooling channel (10) fluidically communicates with the coolant collecting chamber (5), - wherein the at least one cooling channel (10) and at least one stator winding (6) for thermal coupling in an electrically insulating plastic (11) are embedded, - Stator (2) has along the axial direction (A) extending and along a circumferential direction (U) spaced from each other arranged stator teeth (8) which carry the stator windings (6), - electrically insulating plastic (11) with the at least one cooling channel (10) and with the at least one stator winding (6) is arranged in at least one intermediate space (9) formed between two in the circumferential direction (U) adjacent stator teeth (8), - Wherein the electrically insulating plastic (11) by a first plastic material (11a) of a first plastic material and by a second plastic compound (11b) is formed from a second plastic material whose thermal conductivity is greater than the thermal conductivity of the first plastic material.

Description

The invention relates to an electric machine, in particular for a vehicle, as well as a vehicle with such a machine.

Such an electrical machine may generally be an electric motor or a generator. The electric machine can be designed as an external rotor or as an internal rotor.

A generic machine is for example from the US 5,214,325 known. It comprises a housing which surrounds an interior space and which has a jacket radially surrounding the interior in a circumferential direction of the housing, axially on the one hand an axially delimiting the rear wall and axially on the other hand an axially delimiting the front side wall. Firmly connected to the jacket is a stator of the machine. In the stator, a rotor of the machine is arranged, wherein a rotor shaft of the rotor is rotatably supported via a front shaft bearing on the front side wall.

Typically, the stator of a conventional electric machine comprises stator windings which are electrically energized during operation of the machine. This creates heat that must be dissipated to avoid overheating and associated damage or even destruction of the stator. For this purpose, it is known from conventional electrical machines to provide them with cooling for cooling the stator, in particular said stator windings. Such cooling comprises one or more cooling channels, through which a coolant flows and which are arranged in the vicinity of the stator windings in the stator. Heat can be removed from the stator by transferring heat from the stator windings to the coolant.

It proves to be disadvantageous that an efficient heat transfer from the stator to the coolant flowing through the respective cooling channel is associated with considerable design complexity. However, this has a disadvantageous effect on the manufacturing costs of the electrical machine.

It is therefore an object of the present invention to provide an improved embodiment for an electric machine in which this disadvantage is largely or even completely eliminated. In particular, an improved embodiment for an electrical machine is to be created, which is characterized by improved cooling of the stator windings of the stator with simultaneously low production costs.

This object is solved by the subject matter of the independent patent claims. Preferred embodiments are subject of the dependent claims.

The basic idea of the invention is accordingly to embed the stator windings of an electrical machine together with a cooling channel through which cooling can flow for cooling the stator windings into an electrically insulating plastic which is formed by two plastic materials of different thermal conductivity.

Thus, the plastic can act as a heat transfer medium for transferring heat from the stator windings to the coolant on the one hand and as an electrical insulator for the stator windings on the other hand. In this way, in particular a particularly good heat transfer between the stator windings and the guided through the cooling channel coolant is produced. By using an electrically insulating plastic, it is ensured at the same time that the stator windings to be cooled are not electrically short-circuited in an undesired manner.

The use of two plastic materials of different plastic materials with different thermal conductivity makes it possible to resort to an expensive plastic material with high thermal conductivity in areas in which a particularly high thermal conductivity is required for heat dissipation. In areas in which no such high thermal conductivity is required, however, can be used on a - typically cheaper to obtain - plastic. As a result, this procedure leads to considerable cost advantages in the production of the electrical machine.

The direct thermal coupling of the cooling channel with the coolant to the stator windings to be cooled by means of the invention-essential embedding of these two components in the electrically insulating plastic leads to a particularly effective cooling of the stator windings. Thus, even in a high-load operation of the electric machine, it can be ensured that the resulting waste heat can be dissipated from the stator. Damage or even destruction of the electrical machine due to overheating of the stator can thus be avoided.

The production of the electrically insulating plastic can preferably take place by means of injection molding, in which the stator windings to be cooled as well as the cooling channel for the formation of the two plastic masses are encapsulated with the plastic. The embedding of the stator windings and the cooling channel in the plastic masses designed therefore very simple, although two different plastic materials are used. This also results in considerable cost advantages in the production of the electric machine according to the invention.

Another advantage of the solution proposed here is that the second plastic material can act as additional electrical insulation between the stator windings and the stator body. In the event that - due to production - not all stator windings can be completely embedded in the first plastic mass, prevents the second plastic material in any case a possible electrical short circuit with the electrically conductive material of the stator body.

An electric machine according to the invention, in particular for a vehicle, comprises a rotor which is rotatable about an axis of rotation. By the rotation axis, an axial direction of the electric machine is defined. The machine also includes a stator having a plurality of stator windings. The machine further comprises a coolant distribution chamber and an axially spaced-apart coolant collecting chamber. In this case, the coolant distributor chamber communicates fluidically with the coolant collector chamber by means of at least one cooling channel through which a coolant can flow. Preferably, a plurality of such cooling channels are provided between the coolant distributor chamber and the coolant collector chamber.

According to the invention, the at least one cooling channel and the at least one stator winding for thermal coupling to the coolant are embedded in an electrically insulating plastic.

The stator has stator teeth extending along the axial direction and spaced along a circumferential direction, which support the stator windings. The electrically insulating plastic with the at least one cooling channel and with the at least one stator winding is arranged in at least one intermediate space, which is formed between two adjacent stator teeth in the circumferential direction. According to the invention, the electrically insulating plastic is formed by a first plastic mass of a first plastic material and by a second plastic mass of a second plastic material whose thermal conductivity is greater than the thermal conductivity of the first plastic material.

In a preferred embodiment, at least one stator winding is embedded in the first plastic compound of the first plastic material in at least one intermediate space. Furthermore, the first plastic mass with the stator winding embedded therein and the at least one cooling channel are embedded in the second plastic mass of the second plastic material or disposed within the second plastic mass or surrounded by this at least partially or even completely. This measure ensures a particularly good heat transfer between the stator windings and the cooling channel. In addition, said gap between the stator teeth can be used in the production of the plastic materials in the manner of a mold, in which the two plastic materials are injected. This simplifies the production of the plastic materials, since the provision of a separate mold can be omitted.

Particularly preferably, a first and a second plastic compound are arranged in at least two intermediate spaces, preferably in all intermediate spaces. In this way the heat transfer can be optimized.

Suitably, the first plastic material comprises a thermoset or is a thermoset. Alternatively or additionally, the second plastic material may comprise a thermoplastic or be a thermoplastic. With the use of a thermoset with reduced thermal conductivity in those areas that are considered to be less critical in terms of heat transfer, reduced manufacturing costs go hand in hand.

Preferably, the at least one cooling channel is enveloped or surrounded by the first or by the second plastic compound. In this way, a particularly good thermal connection of the coolant flowing through the cooling channel is ensured with the stator winding.

According to a preferred embodiment, the coolant distributor space and / or the coolant collector space for thermal coupling to the stator windings are arranged at least partially in the electrically insulating plastic, preferably in the first plastic mass. This allows a particularly good heat transfer between the coolant distributor chamber or the coolant collector chamber and the stator windings, so that the coolant distributor chamber or the coolant collector chamber can also be used for direct absorption of heat from the stator windings.

Suitably, the space limiting surface portions of the stator are coated with the second plastic composition. This measure improves the electrical insulation of the stator windings relative to the stator body.

Particularly preferably, the first and the second plastic mass together substantially fill the at least one intermediate space completely off. In this way, the formation of undesirable gaps, such as in the form of air gaps, which would lead to an undesirable reduction in heat transfer, avoided.

In another preferred embodiment, the first and the second plastic mass are an injection molding compound of the first and second plastic material. The application of an injection molding process simplifies and accelerates the production of the plastic materials. This leads to cost advantages in the production of electrical machine.

In an advantageous development, the stator comprises a, preferably annular, stator body, from which the stator teeth can protrude. In this development, the first plastic compound is arranged at least on an outer peripheral side of the stator body. In this way, the stator can be electrically isolated from the external environment of the machine. The provision of a separate housing for receiving the stator body can thus be omitted. A coating of at least one or both end faces of the stator body with the first plastic compound is also conceivable in an optional variant. In a further variant, the plastic compound can envelop the stator body, preferably completely. Particularly preferably, the first plastic compound forms an outer coating on the outer peripheral side. In this way, the stator body is electrically insulated on the outer peripheral side. The provision of a separate housing for receiving the stator body can thus be omitted. A coating of at least one or both end faces of the stator body with the first plastic compound is also conceivable in an optional variant. In a further variant, the plastic compound may cover the stator body, preferably completely.

A further preferred embodiment proposes to divide the intermediate space into a first and a second subspace. In this embodiment, the at least one stator winding is arranged in the first subspace. In the second subspace of at least one cooling channel is arranged. Between the two subspaces a positioning aid is formed, by means of which the at least one cooling channel can be positioned in the second subspace. This measure allows a precise and stable positioning of the cooling channel - which is typically a tubular body or a flat tube - when it is molded together with the stator windings in the space between the two stator teeth with the plastic material resulting in the two plastic masses.

In an advantageous development of this embodiment, the positioning aid comprises two projections, which are formed on two stator teeth adjacent in the circumferential direction. The two projections face each other in the circumferential direction of the rotor and protrude into the gap for positioning the cooling passage. This embodiment allows a particularly accurate alignment of the cooling channel in the intermediate space before encapsulation with the plastic of the plastic mass.

Expediently, the first plastic mass protrudes axially, preferably on both sides, out of the respective intermediate space. Thus, the first plastic mass can also be used for partially delimiting the coolant distributor space or the coolant collector space. In particular, a required in the course of the manufacture of the machine removal of the protruding from the intermediate space portion of the first plastic composition can be omitted, which is associated with cost advantages in the manufacture of the machine.

A further advantageous embodiment therefore proposes that the first plastic mass at least partially limits the coolant distributor space and / or the coolant collector space. The provision of a separate boundary for the coolant distributor chamber or the coolant collector chamber, for example in the form of a housing, can thus be dispensed with.

It is expedient for at least one cooling channel as well as the first and second plastics material to be provided in each case in at least one, preferably in each intermediate space, between two stator teeth each adjacent in the circumferential direction. In this way it is ensured that operatively generated waste heat can be dissipated from all existing stator windings.

According to another preferred embodiment, the at least one cooling channel is arranged radially outside or radially inside the respective stator winding in the intermediate space. This allows a space-efficient arrangement of the cooling channel close to the stator windings to be cooled, so that the electrical machine for cooling the stator windings requires little space.

Alternatively, at least one cooling channel can be arranged radially outside and additionally at least one further cooling channel can be arranged radially inside the respective stator winding in the intermediate space. In this variant, therefore, at least two cooling channels are provided for cooling the stator winding, whereby an increased cooling capacity is effected.

A preferred embodiment proposes to form the at least one cooling channel as a tubular body which surrounds a tubular body interior. In this variant, at least one pipe body Dividing element formed, which divides the tube body interior in at least two fluidly separated from each other cooling channels. By means of said separating elements of the tubular body can be stiffened, so that increases its mechanical strength. The tubular body may be formed by an electrically conductive material, in particular a metal, or by an electrically insulating material, in particular a plastic.

An advantageous development proposes to form the tubular body as a flat tube, which extends along the axial direction and has two broad sides and two narrow sides in a cross section perpendicular to the axial direction. Expediently, in the cross section perpendicular to the axial direction, at least one broad side of the flat tube extends substantially perpendicular to the radial direction. A length of the two broad sides may preferably be at least four times, preferably at least ten times, a length of the two narrow sides.

According to a further preferred embodiment, the coolant distributor chamber and / or the coolant collector chamber are formed by a cavity which is present at least partially, preferably completely, in the first plastic mass. The provision of a separate enclosure or a housing for limiting the coolant distributor or coolant collector space can thus be dispensed with. This is accompanied by not inconsiderable cost advantages.

The invention further relates to a vehicle, in particular a motor vehicle with a previously presented electric machine. The above-explained advantages of the electric machine are therefore also transferred to the vehicle according to the invention.

Other important features and advantages of the invention will become apparent from the dependent claims, from the drawings and from the associated figure description with reference to the drawings.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination given, but also in other combinations or in isolation, without departing from the scope of the present invention.

Preferred embodiments of the invention are illustrated in the drawings and will be explained in more detail in the following description.

• 1 ein Beispiel einer erfindungsgemäßen elektrischen Maschine in einem Längsschnitt entlang der Rotationsachse des Rotor,
• 2 den Stator der elektrischen Maschine gemäß 1 in einem Querschnitt senkrecht zur Rotationsachse des Rotors,
• 3 eine Detaildarstellung des Stators der 2 im Bereich eines Zwischenraum zwischen zwei in Umfangsrichtung benachbarten Statorzähnen,
• 4 eine Weiterbildung der Variante gemäß 3,
• 5 eine erste Variante der elektrischen Maschine der 1, bei welcher das durch die Kühlkanäle strömende Kühlmittel auch zur Kühlung der Wellenlager des Rotors verwendet wird,
• 6 eine zweite Variante der elektrischen Maschine gemäß 1, welche besonders wenig Bauraum beansprucht,
• 7 eine dritte Variante der Maschine gemäß 1, welche eine besonders effektive Kühlung der Statorwicklungen ermöglicht.

It show, each schematically:

• 1 an example of an electrical machine according to the invention in a longitudinal section along the axis of rotation of the rotor,
• 2 the stator of the electric machine according to 1 in a cross section perpendicular to the axis of rotation of the rotor,
• 3 a detailed view of the stator of 2 in the region of a gap between two circumferentially adjacent stator teeth,
• 4 a development of the variant according to 3 .
• 5 a first variant of the electric machine of 1 in which the coolant flowing through the cooling channels is also used to cool the shaft bearings of the rotor,
• 6 a second variant of the electric machine according to 1 , which takes up very little space,
• 7 a third variant of the machine according to 1 , which allows a particularly effective cooling of the stator windings.

1 illustrates an example of an electric machine according to the invention 1 in a sectional view. The electric machine 1 is dimensioned so that it can be used in a vehicle, preferably in a road vehicle.

The electric machine 1 includes one in the 1 only roughly illustrated rotor 3 and a stator 2 , For clarification, the stator 2 in 2 in a cross section perpendicular to the axis of rotation D along the section line II - II of the 1 shown in a separate representation. Corresponding 1 owns the rotor 3 a rotor shaft 31 and can several, in the 1 not shown magnets whose magnetic polarization along the circumferential direction U alternates. The rotor 3 is about a rotation axis D rotatable, whose position through the central longitudinal axis M the rotor shaft 31 is fixed. By the rotation axis D, an axial direction A is defined, which is parallel to the axis of rotation D extends. A radial direction R is perpendicular to the axial direction A , A circumferential direction U rotates around the axis of rotation D ,

As 1 reveals is the rotor 3 in the stator 2 arranged. Thus, it is in the electric machine shown here 1 around a so-called inner rotor. Conceivable, however, is a realization as a so-called external rotor, in which the rotor 3 outside the stator 2 is arranged. The rotor shaft 31 is in a first shaft bearing 32a and, axially spaced therefrom, in a second shaft bearing 32b around the axis of rotation D rotatable on the stator 2 stored.

The stator 2 Also includes in a known manner a plurality, for generating a magnetic field electrically energizable stator windings 6 , By magnetic interaction of the magnet of the rotor 3 generated magnetic field with that of the stator windings 6 generated magnetic field becomes the rotor 3 set in rotation.

The cross section of 2 If you take that, the stator 2 an annular stator body 7 , For example, of iron, may have. In particular, the stator body 7 from several, along the axial direction A be formed stacked and glued together stator body plates (not shown). On the stator body 7 are radially inside several stator teeth 8th molded, extending along the axial direction A extend radially inward from the stator body 7 protrude away and along the circumferential direction U spaced apart from each other. Every stator tooth 8th carries a stator winding 6 , The individual stator windings 6 together form a winding arrangement. Depending on the number of stator windings 6 To be formed magnetic poles, the individual stator windings 6 the entire winding assembly be suitably electrically wired together.

In operation of the machine 1 generate the electrically energized stator windings 6 Waste heat from the machine 1 must be removed to prevent overheating and concomitant damage or even destruction of the machine 1 to prevent. Therefore, the stator windings become 6 cooled by a coolant K, which passes through the stator 2 is guided and that of the stator windings 6 generated waste heat absorbs by heat transfer.

To the coolant K through the stator 2 to lead, includes the machine 1 a coolant distribution chamber 4 in which via a coolant inlet 33 a coolant K can be introduced. Along the axial direction A at a distance to the coolant distribution chamber 4 is a coolant collector room 5 arranged. The coolant distribution chamber 4 communicates by means of several cooling channels 10 , of which in the representation of 1 only one can be seen fluidly with the coolant collecting space 5 , In a cross section, not shown in the figures, perpendicular to the axial direction A, the coolant distributor space can be used 4 and the coolant collector room 5 each have an annular geometry. Along the circumferential direction U are several cooling channels 10 spaced from each other, each extending along the axial direction A from the annular coolant distribution chamber 4 to the annular coolant collector space 5 extend. Thus, this can be done via the coolant inlet 33 in the coolant distribution chamber 4 introduced coolant purchase the individual cooling channels 10 be distributed. After flowing through the cooling channels 10 and the absorption of heat from the stator windings becomes the coolant K in the coolant receiver space 5 collected and one on the stator 2 provided coolant outlet 34 back out of the machine 1 discharged.

Like the representations of the 1 and 2 can be seen, are the stator windings 6 in intervals 9 arranged between each two in the circumferential direction U adjacent stator teeth 8th are formed. Said interspaces 9 are also known to the person skilled in the art as so-called "stator slots" or "stator slots" which, like the stator teeth, are known 8th along the axial direction A extend.

Now, pay attention to the presentation of the 3 directed, one between two in the circumferential direction U adjacent stator teeth 8th - in the following also as stator teeth 8a . 8b designated - trained space 9 in a detailed view shows. To the heat transfer from the stator windings 6 generated waste heat on the through the cooling channels 10 flowing coolant K to improve is accordingly 3 in the interstices 9 each an electrically insulating plastic 11 intended. The electrically insulating plastic 11 is through a first plastic mass 11a of a first plastic material and a second plastic mass 11b formed of a second plastic material whose thermal conductivity is greater than the thermal conductivity of the first plastic material. The first plastic material 11a is a thermoset. The second plastic material 11b is a thermoplastic. In the example scenario are in all intervals 9 in each case a first and a second plastic compound 11a . 11b arranged.

According to 3 are those in the gap 9 arranged stator windings 6 and a cooling channel 10 in the first plastic mass 11a embedded from the first plastic material. The first plastic mass 11a with the stator winding embedded therein 6 and with the cooling channel 10 are again in the second plastic mass 11b embedded or partially surrounded by the second plastic material. As 3 reveals, is the cooling channel 10 in the cross section perpendicular to the axial direction A completely from the second plastic mass 11b envelops.

Preference is given to the two plastic materials 11a . 11b each injection molding compounds of the electrically insulating plastic. The application of a Injection molding process simplifies and speeds up the production of the plastic compound.

It goes without saying that the according to 3 in the gap 9 arranged stator winding 6 each partially a first stator winding 6a belonging to a first stator tooth 8a is supported, and partially a second stator winding 6b assigned to the one of the first stator tooth 8a in the circumferential direction U adjacent, second stator tooth 8b worn. To clarify this scenario, see 3 a virtual dividing line 12 located. In the 3 to the left of the dividing line 12 shown winding wires 13a belong to that of the stator tooth 8a carried stator winding 6a , The right of the dividing line 12 shown winding wires 13b belong to that of the stator tooth 8b carried stator winding 6b ,

Like the detail of the 3 occupied, the cooling channels can 10 each through a tubular body 16 , For example, be formed of aluminum, which has a tubular body interior 22 surrounds. Basically comes as a material for the tubular body 16 or for the cooling channel 10 an electrically conductive material, in particular a metal, or an electrically insulating material, in particular a plastic, into consideration. Optionally, as in the detailed representation of the 3 shown on the tubular body 16 one or more separating elements 18 be formed, which is the cooling channel 10 in fluidly separate subcooling channels 19 divided. In this way, the flow behavior of the coolant K in the cooling channel 10 be improved, whereby an improved heat transfer to the coolant K is accompanied. In addition, the tube body 16 additionally stiffened mechanically in this way. In 3 exemplify three such separators 18 shown, so that four partial cooling channels 19 result. Of course, in variants of the example, a different number of separating elements 18 possible. The the cooling channel 10 forming tubular body 16 is as a flat tube 17 formed, which in a cross section perpendicular to the axis of rotation D of the rotor 3 (see. 3 ) two broadsides 20 and two narrow sides 21 has. In the in 3 shown cross section perpendicular to the axial direction A extend the two broadsides 20 of the flat tube 17 perpendicular to the radial direction R. A length of the two broad sides 20 is at least four times, preferably at least ten times, a length of the two narrow sides 21 ,

In the example of 1 to 3 is the cooling channel 10 radially outside the stator windings 6 in each space 9 arranged. The radial distance of the cooling channels 10 to the axis of rotation D of the rotor 3 is therefore larger than that of the stator windings 6 to the axis of rotation D , It is also conceivable, however, an arrangement of the cooling channel 10 radially inside.

For the production of an electrical machine 1 according to the 1 to 3 be first through the tubular body 16 or flat tubes 17 formed cooling channels 10 in the interstices 9 brought in. Then the spaces become 9 limiting surfaces of the stator body 7 with the second plastic material, preferably a thermoplastic, overmolded and in this way the second plastic mass 11b educated. In this way, the material of the stator body 7 to the respective gap 9 electrically isolated. After that, the stator windings 6 in the interstices 9 introduced and on the stator teeth 8th arranged. After that, the stator windings 6 with the first plastic mass 11a resulting first plastic material, preferably a thermoset, encapsulated. In the course of manufacturing the electrically insulating plastic 11 that is made up of the two plastic masses 11a . 11b can also be made of the stator body 7 with the first plastic mass 11a forming first plastic material to be encapsulated.

According to 3 can the gap 9 a first subspace 9c in which the stator winding 6 is arranged, and a second subspace 9d include, in which the cooling channel 10 is arranged and which the first subspace 9c to the gap 9 added. As the 3 and 4 can be seen, between the two subspaces 9c . 9d a positioning aid 27 be arranged, by means of which the cooling channel 10 in the second subspace 9d is fixed. Said positioning aid 27 includes two protrusions 28a . 28b at the two in the circumferential direction U adjacent and the gap 9 limiting stator teeth 8a . 8b are formed. The two projections 28a . 28b are each other in the circumferential direction U facing and protrude for positioning of the cooling channel 10 in the gap 9 into it. The projections 28a . 28b act as the tubular body 16 or flat tube 17 trained cooling channel 10 as a radial stop, the undesired movement of the cooling channel 10 , in particular when producing the plastic materials 11a . 11b can prevent radially inward by injection molding.

The 4 shows a development of the example of 3 , The further education of 4 differs from the example of 3 in that in the space 9 not only radially outside, but also radially inside a cooling channel 10 is provided, as in the example of 3 as a tubular body 16 or as a flat tube 17 can be trained. An example is the radially inner cooling channel 10 as a flat tube 17 with two dividers 18 and three partial cooling channels 19 shown. The above explanations for example the 3 apply mutatis mutandis mutatis mutandis, as far as appropriate for the example of 4 ,

The following will be back to the 1 Referenced. As the 1 clearly demonstrated, the preferably integrally formed, first plastic mass 11a axially on both sides of the spaces 9 protrude. This also allows the coolant distribution chamber 4 and, alternatively or additionally, the coolant collector space 5 for thermal coupling to the two axial end sections 14a . 14b the respective stator winding 6 in the plastic compound 11 to embed, the axially outside the respective space 9 are arranged. In this way, also in the region of the usually thermally particularly loaded axial end portions 14a . 14b the relevant stator winding 6 an effective heat transfer with the in the coolant distribution chamber 4 or coolant collector space 5 existing coolant K are produced. This measure allows a particularly effective cooling of the two axial end sections 14a . 14b the stator winding 6 ,

Furthermore, according to 1 the stator 2 with the stator body 7 and the stator teeth 8th axially between a first and a second end shield 25a . 25b arranged.

As the 1 is part of the coolant distribution chamber 4 in the first bearing shield 25a and a part of the coolant reservoir space 5 in the second bearing plate 25b arranged. The coolant distribution chamber 4 and the coolant collector room 5 are thus each partially by one in the first plastic mass 11a provided cavity 41a . 41b educated.

The first cavity 41a is thereby by a in the first bearing plate 25a trained cavity 42a to the coolant distribution chamber 4 added. Accordingly, the second cavity 41b through one in the second end shield 25b trained cavity 42b to the coolant collector room 5 added. In the embodiment described above limits the plastic mass 11a the coolant distribution chamber 4 as well as the coolant collector space 5 So at least partially.

In the first bearing shield 25a can also be a coolant supply 35 be formed, which the coolant distribution space 4 Fluidic with an outside, especially as in 1 shown on the circumference, on the first end shield 25a provided coolant inlet 33 combines. In the second bearing plate 25b can accordingly a coolant removal 36 be formed, which the coolant collector space 5 Fluidic with an outside, especially as in 1 shown on the circumference, on the end shield 25b provided coolant outlet 34 combines. This allows an arrangement of the coolant distribution chamber 4 or the coolant collector space 5 each radially outward at the first and second end portion 14a . 14b the relevant stator winding 6 and also in the extension of these end sections 14a . 14b along the axial direction A , The operation of the machine 1 thermally particularly stressed end sections 14a . 14b the stator windings 6 are also cooled particularly effectively by this measure.

According to 1 can be the first plastic mass 11a from the electrically insulating plastic 11 also on an outer peripheral side 30 of the stator body 7 be arranged and thus on the outer peripheral side 30 a plastic coating 11.1 form. Thus, the stator body typically formed of electrically conductive stator plates 7 of the stator 2 be isolated electrically against the environment. The provision of a separate housing for receiving the stator body 7 can thus be omitted.

The 5 shows a variant of the example of 1 , To also the rotor shaft 31 as well as the two shaft bearings 32a . 32b during operation of the machine 1 To cool, the coolant supply 35 thermally to the first bearing plate 25a arranged, first shaft bearings 32a be coupled. Likewise, the coolant discharge 36 thermally to the second bearing plate 25b arranged, second shaft bearing 32b be coupled. A separate cooling device for cooling the shaft bearings 32a . 32b can be omitted in this way, resulting in not inconsiderable cost advantages. In the example of 5 are the coolant inlet 33 and the coolant outlet 34 on the outer front side 26a . 26b of the respective end shield 25a . 25b intended. It is also conceivable, however, a circumferential or radial arrangement. In the variant according to the 5 and 1 are the stator windings 6 with respect to the radial direction R radially within the cooling channels 10 arranged.

The stator windings 6 are with an electrical connection 50 through one in the second end shield 25b intended implementation 39 from the stator 2 out to the outside, so that they can be electrically energized from the outside. The implementation 39 is radially between the coolant distribution chamber 4 or the coolant collector space 5 and the rotation axis D arranged.

In the example of 6 which one opposite the 5 simplified embodiment shows are the coolant distribution chamber 4 and the coolant collector room 5 exclusively in the axial extension of the cooling channels 10 arranged. This variant requires for the coolant distribution chamber 4 as well as for the coolant collector room 5 very little space.

In the variant according to 6 are the stator windings 6 with respect to the radial direction R radial inside the cooling channels 10 arranged. The stator windings 6 are with an electrical connection 50 through one in the second end shield 25b intended implementation 39 from the stator 2 out to the outside, so that they can be electrically energized from the outside. The implementation 39 is with respect to the radial direction radially outside of the coolant distribution chamber 4 or the coolant collector space 5 in the second bearing plate 25b arranged.

In the example of 7 is a further education of 5 shown. In this development, the coolant distribution chamber surrounds 4 in the 7 illustrated longitudinal section along the axis of rotation D, the first axial end portion 14a the respective stator winding 6 U-shaped, ie axially end and radially inward and radially outward. Accordingly, the coolant collector chamber surrounds 5 in the longitudinal section along the axis of rotation D, the second axial end portion 14b the respective stator winding 6 U-shaped, ie axially end and radially inward and radially outward. In this variant are cooling channels 10 both radially inside and radially outside the stator winding 6 intended. Thus, the respective stator windings 6 including their axial end portions 14a . 14b over the cooling channels 10 as well as the coolant distribution chamber 4 as well as the coolant collector space 5 in direct thermal contact with the coolant K , This allows a particularly effective cooling of the stator winding 6 including the thermally stressed special axial end sections 14a . 14b ,

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely 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.

Cited patent literature

• US 5214325 [0003]

Claims (20)

Electric machine (1), in particular for a vehicle, - With a rotor (3) which is rotatable about an axis of rotation (D) through which an axial direction (A) of the electric machine (1) is defined, and with a stator (2) having stator windings (6), - With a coolant distribution chamber (4) and an axially spaced therefrom arranged coolant collecting chamber (5), wherein the coolant distribution chamber (4) for cooling the stator windings (6) by means of at least one of a coolant (K) flow-through cooling channel (10) fluidly with the Coolant collector chamber (5) communicates, wherein the at least one cooling channel (10) and at least one stator winding (6) for thermal coupling are embedded in an electrically insulating plastic (11), - wherein the stator (2) has along the axial direction (A) extending and along a circumferential direction (U) spaced from each other arranged stator teeth (8) which carry the stator windings (6), - wherein the electrically insulating plastic (11) is arranged with the at least one cooling channel (10) and with the at least one stator winding (6) in at least one intermediate space (9) between two in the circumferential direction (U) adjacent stator teeth (8). is trained, - Wherein the electrically insulating plastic (11) by a first plastic material (11a) of a first plastic material and by a second plastic compound (11b) is formed from a second plastic material whose thermal conductivity is greater than the thermal conductivity of the first plastic material. Electric machine after Claim 1 , characterized in that - in which at least one intermediate space (9) at least one stator winding (6) is embedded in the first plastic compound (11a) of the first plastic material, - the first plastic compound (11a) with the stator winding (6) and embedded therein the at least one cooling channel (10) at least partially surrounded by the second plastic compound (11b) of the second plastic material, preferably embedded in this, are. Electric machine after Claim 1 or 2 , characterized in that in at least two intermediate spaces (9), preferably in all intermediate spaces (9), both the first and the second plastic compound (11a, 11b) are arranged. Electrical machine according to one of the preceding claims, characterized in that - the first plastic material comprises a thermoset or is a thermoset, and / or that - the second plastic material comprises a thermoplastic or is a thermoplastic. Electrical machine according to one of the preceding claims, characterized in that the at least one cooling channel (10) of the electrically insulating plastic (11), preferably of the first or second plastic compound (11a, 11b), wrapped or surrounded. Electrical machine according to one of the preceding claims, characterized in that the coolant distributor chamber (4) and / or the coolant collector chamber (5) for thermal coupling to the stator windings (6) at least partially in the electrically insulating plastic (11), preferably in the first plastic mass (11a) are arranged. Electrical machine according to one of the preceding claims, characterized in that the intermediate space (9) delimiting surface portions (11.1) of the stator (2) are at least partially coated with the second plastic compound (11b). Electric machine according to one of the preceding claims, characterized in that the first and the second plastic compound (11a, 11b) together substantially completely fill the intermediate space (9). Electric machine according to one of the preceding claims, characterized in that the first and the second plastic compound (11a, 11b) are formed by an injection molding of the first and second plastic material. Electric machine according to one of the preceding claims, characterized in that - the stator (2) comprises a, preferably annular, stator body (7), - the first plastic compound (11a) is arranged at least on an outer peripheral side (30) of the stator body (7) , Electrical machine according to one of the preceding claims, characterized in that the first plastic compound (11a) on the outer peripheral side (30) forms an outer coating (11.1). Electric machine according to one of the preceding claims, characterized in that - the intermediate space (9) has a first subspace (9c), in which the at least one stator winding (6) is arranged, and a second subspace (9d), in in which the at least one cooling channel (10) is arranged comprises, - a positioning aid (27) is arranged between the two subspaces (9c, 9d) by means of which the at least one cooling channel (10) can be positioned in the second subspace (9d). Electric machine after Claim 12 characterized in that the positioning aid (27) comprises two projections (28a, 28b) formed on two stator teeth (8a, 8b) adjacent in the circumferential direction (U), - the two projections (28a, 28b) face each other in the Circumferentially facing (U) and for positioning of the cooling channel (10) protrude into the intermediate space (9). Electric machine according to one of the preceding claims, characterized in that at least the first plastic mass (11a) protrudes axially from the intermediate space (9). Electrical machine according to one of the preceding claims, characterized in that the first plastic compound (11a) at least partially delimits the coolant distributor chamber (4) and / or the coolant collector chamber (5). Electric machine according to one of the preceding claims, characterized in that in at least one, preferably in each, intermediate space (9) between two each in the circumferential direction (U) adjacent stator teeth (8a, 8b) at least one cooling channel (10) and the electrically insulating plastic (11) are provided. Electric machine according to one of the preceding claims, characterized in that - the at least one cooling channel (10) radially outside or radially within the respective stator winding (6) in the intermediate space (9) is arranged, or that - at least one cooling channel (10) radially outward and at least one further cooling channel (10) is arranged radially inside the respective stator winding (6) in the intermediate space (9). Electrical machine according to one of the preceding claims, characterized in that the at least one cooling channel (10) is formed as a tubular body (16) surrounding a tubular body interior (22), wherein on the tubular body (16) at least one separating element (18) is formed, which subdivides the tube body interior (22) into at least two fluid cooling channels (19) which are separated from one another by fluid. Electrical machine according to one of the preceding claims, characterized in that the tubular body (16) as a flat tube (17) is formed, wherein in a cross section perpendicular to the axial direction (A) at least one broad side (20) of the flat tube (17) substantially extends perpendicular to the radial direction (R). Vehicle, in particular motor vehicle, with at least one electric machine (1) according to one of the preceding claims.

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