WO2018087017A1 - Stator for an electrical machine, in particular belonging to a motor vehicle, and an electrical machine, in particular for a motor vehicle - Google Patents

Abstract

The invention relates to a stator (1) for an electrical machine (2), in particular belonging to a motor vehicle, the stator comprising at least one laminated core (4) in which a plurality of cooling channels (8) extending in an axial direction (9) of the stator (1) is formed, through which channels a cooling fluid for cooling the stator can flow, wherein each cooling channel (8) is peripherally delimited by the laminated core (4) so as to be completely enclosed.

Description

 Stator for an electrical machine, in particular a motor vehicle, as well as an electric machine, in particular for a motor vehicle

The invention relates to a stator for an electrical machine, in particular a motor vehicle, according to the preamble of patent claim 1, as well as an electric machine, in particular for a motor vehicle, according to the preamble of

Claim 12.

Such a stator for an electrical machine, in particular a motor vehicle, as well as such an electric machine, in particular for a motor vehicle, are already known, for example, from DE 10 2001 1 053 299 A1. The stator has at least one laminated core, in which a plurality of cooling passages extending from a cooling fluid for cooling the stator and extending in the axial direction of the stator are formed.

In addition, EP 1 271 747 A1 discloses a medium frequency electric motor with a liquid-filled stator separated from a rotor by a split tube. The split tube is liquid-tight stored in bearing flanges.

DE 10 2014 213 159 A1 discloses an arrangement for stator cooling for an electric motor, comprising a stator lamination stack comprising a plurality of axially aligned stator laminations and a plurality of winding slots running axially in the stator lamination stack for accommodating associated stator windings.

Furthermore, an electric machine is known from DE 10 201 1 003 597 A1, which has a stator with a laminated stator core and a stator winding arranged on the laminated stator core. Object of the present invention is to develop a stator and an electric machine of the type mentioned in such a way that a particularly

advantageous cooling of the stator can be realized.

 This object is achieved by a stator with the features of claim 1 and by an electric machine with the features of claim 12. Advantageous embodiments of the invention are

Subject of the dependent claims.

A first aspect of the invention relates to a stator for an electrical machine, in particular a motor vehicle. In this case, the stator has at least one laminated core, in which a plurality of cooling channels, which can flow through a cooling fluid, in particular a cooling fluid, for cooling the stator and which extend in the axial direction of the stator, are formed.

In order to be able to realize a particularly advantageous and in particular efficient and effective cooling of the stator, it is inventively provided that the respective cooling channel is limited in its circumferential direction completely encircling by the laminated core. As a result, a particularly advantageous and effective and efficient heat transfer from what also referred to as stator lamination stack

Laminated core to the cooling channel flowing through the cooling fluid, so that in a short time a particularly large amount of heat from the laminated core and thus from the stator can be transported in total. Preferably, the respective cooling channel in its circumferential direction is completely circulating directly through the

Limited laminated core, so that the coolant channel flowing through the respective cooling channel directly flows or flows around the laminated core or the respective cooling channel directly bounding wall region of the laminated core and thus directly touch or

can contact. As a result, the laminated core can be cooled particularly effectively.

A further advantage of the stator according to the invention is that the respective cooling channel extends within the laminated core and has a longitudinal extension which extends at least substantially in the axial direction of the stator and thus of the laminated core or substantially parallel to the axial direction of the stator and thus of the laminated core , The respective, fluid-flowed cooling channel is thus not outside the stator or the laminated core, but within the laminated core and thus disposed within a magnetically active part of the stator. The invention is based in particular on the knowledge that, in the case of a conventionally provided water jacket cooling, the heat flow must traverse the entire stator yoke, since the heat is generated primarily in the winding. For the required cooling capacity, this is a comparatively high

Thermal resistance. Typically, in the Statorjoch a temperature drop of 30 ° C prevail. If this were bypassed, the electric machine would be cooler by this amount or the continuous power could be increased. Thus, in conventional electric machines there is the problem that the continuous power is lower than desired or that the electric machine is larger and thus

more costly than necessary to design. These problems and disadvantages can be avoided by means of the stator according to the invention, since a particularly efficient and effective cooling can be realized.

The respective cooling channel is designed, for example, as a cooling tube through which the cooling fluid can flow, wherein the respective cooling channel formed, for example, as a cooling tube has an at least substantially circular, νοη, the cooling fluid

having flow-through cross-section.

However, in order to realize a particularly efficient and effective cooling of the laminated core and thus the stator as a whole, it is at an advantageous

Embodiment of the invention provided that the respective cooling channel as

Cooling slot is formed, which can be traversed by the cooling fluid cross section has a width substantially greater than the height. This allows a particularly effective and efficient heat transfer from the laminated core to the coolant channel flowing through the cooling fluid, so that in a short time a particularly high

Quantity of heat can be removed from the laminated core.

The cooling fluid is preferably a cooling fluid, in particular an oil, wherein the cooling fluid is also referred to as a cooling medium. By using the cooling liquid as the cooling fluid, a particularly effective cooling can be represented. Due to the design of the respective cooling channel as a cooling slot is a so-called

Slit cooling of the stator can be realized, so that the stator can be cooled particularly effectively. Another embodiment is characterized in that the width of the

Cooling slit at least 2.5 times larger, in particular at least 3 times larger than the height. As a result, a particularly high cooling capacity can be realized.

In a further embodiment of the invention, the respective cooling channel extends at least over more than half of the running in the axial direction of the stator length of the laminated core, in particular without interruption. As a result, the stator can be cooled particularly effectively.

 Preferably, the cooling channel has at least one length region, which extends through it in the axial direction of the laminated core. At least in this length range, the cooling channel in its circumferential direction is completely circulated through the laminated core, in particular directly limited. In this case, at least this length region extends without interruption at least over more than half of the length of the laminated core running in the axial direction of the stator. In particular, the length region extends over the entire length of the laminated core extending in the axial direction, so that the length region, for example, extends completely without interruption. In a particularly advantageous embodiment of the invention, it is thus provided that the respective cooling channel extends in the axial direction completely through the laminated core, so that the laminated core can be cooled effectively and efficiently over an entire axial length.

In a further embodiment of the invention, the laminated core has a plurality of successively in the circumferential direction of the laminated core teeth and a plurality of circumferentially of the laminated core, between the teeth arranged grooves for at least partially receiving at least one winding of the stator. In other words, exactly one of the teeth is arranged in the circumferential direction of the laminated core between two circumferentially directly successive grooves, so that in the circumferential direction in pairs between each two of the grooves exactly one of the teeth of the laminated core is arranged.

In order to realize a particularly effective and efficient cooling of the stator, at least one of the cooling channels is at least partially arranged in the respective tooth, so that at least one of the cooling channels runs at least partially in the respective tooth. The cooling channel is thus formed as a tooth channel, wherein it tooth channel at least partially in the circumferential direction, insbesondre particular at least predominantly or completely, between two circumferentially immediately consecutive of the grooves is arranged.

It has been found to be particularly advantageous if the at least one

Cooling channel runs completely in the respective tooth. This embodiment is based on the finding that, in particular in the region of the winding, which is held on the tooth or wound around the tooth, a particularly high amount

Heat energy can arise. Since now the cooling channel extends at least partially, in particular at least predominantly or woolly, through the tooth, heat energy can be transported particularly advantageous from the tooth and the laminated core in total.

 In order to be able to remove a particularly high amount of heat energy from the respective tooth, it is provided in a further embodiment of the invention that run in the respective tooth more of the cooling channels at least partially.

It has been found to be particularly advantageous if the plurality, each extending at least partially in the respective tooth cooling channels in the radial direction of the stator are arranged successively or one behind the other.

As a result, heat energy can be removed from the laminated core particularly effective.

Finally, it has proven to be particularly advantageous if at least one of the cooling channels in a parallel to the axial direction of the stator extending first direction and at least one of the cooling channels in a direction parallel to the axial direction of the stator and the first direction opposite second direction of the cooling fluid can be flowed through. In other words, it is preferably provided that, during operation of the electric machine, the cooling fluid flows in the first direction through the at least one cooling channel and in the first opposite second direction through the at least one other cooling channel, so that the cooling fluid in opposite directions the cooling channels flows. As a result, a particularly high cooling capacity can be realized.

A second aspect of the invention relates to an electrical machine, in particular for a motor vehicle. The electric machine comprises at least one stator, in particular at least one stator according to the invention, which at least one Laminated core. A plurality of cooling passages through which a cooling fluid can flow for cooling the stator and extending in the axial direction of the stator are formed in the laminated core.

In order to be able to realize a particularly effective cooling of the starter and thus of the electric machine as a whole, it is in the second aspect of

Invention provided that the respective cooling channel is limited in its circumferential direction completely encircling by the laminated core. Advantages and advantageous embodiments of the first aspect of the first invention are to be regarded as advantages and advantageous embodiments of the second invention and vice versa.

Further details of the invention will become apparent from the following description of a preferred embodiment with the accompanying drawings. Showing:

 1 shows a detail of a schematic and sectional front view of a stator according to a first embodiment of an electric machine, with at least one laminated core in which a plurality of cooling fluid for cooling the stator and can be flowed through in the axial direction of the stator extending cooling channels is formed wherein the respective cooling channel is limited in its circumferential direction completely circumferentially by the laminated core;

Fig. 2 is a schematic and perspective side view of the electrical

 Machine with the stator according to a second embodiment;

Fig. 3 is a schematic and sectional side view of the electrical

 Machine with the stator according to a third embodiment; and

Fig. 4 is a schematic and sectional front view of the stator according to a fourth embodiment

In the figures, the same or functionally identical elements are the same

Provided with reference numerals.

Fig. 1 shows a detail in a schematic and sectional front view of a generally designated 1 stator according to a first embodiment of an electrical machine, in particular a motor vehicle. The motor vehicle is designed, for example, as a hybrid or electric vehicle and, in its completely manufactured state, comprises the electric machine by means of which the motor vehicle can be driven. For this purpose, the electric machine is operable, for example, in a motor operation and thus as an electric motor. In conjunction with FIG. 3, it can be seen that the electric machine designated by 2 in FIGS. 2 and 3 comprises the stator 1 and a rotor 3 which, for example, is arranged at least partially or completely in the stator 1. The rotor 3 is rotatable about an axis of rotation relative to the stator 1.

From Fig. 1 it can be seen that the stator 1 has at least one laminated core 4, which comprises a yoke 5 and a plurality of circumferentially of the stator 1 and thus of the laminated core 4 successively or successively arranged teeth 6, which connected to the yoke 5 are. The yoke 5 is also referred to as a stator yoke, wherein the teeth 6 are also referred to as stator teeth.

For example, the teeth 6 are formed integrally with the yoke 5. In addition, the laminated core 4 has a plurality of in the circumferential direction of the stator 1 and thus the laminated core 4 consecutive grooves 7, wherein in the circumferential direction of the laminated core 4 between each two in the circumferential direction of the laminated core 4th

immediately following one of the grooves 7 exactly one of the teeth 6 is arranged. Thus, exactly one of the teeth 6 is arranged in pairs between two of the grooves 7.

As can also be seen from FIG. 1, a plurality of cooling passages 8, which are flowed through by a cooling fluid for cooling the laminated core 4 and thus of the stator 1 and extend in the axial direction of the stator 1 and thus of the laminated core 4, are formed in the laminated core 4. In Fig. 1 and Fig. 2, the axial direction of the stator 1 and thus of the laminated core 4 is illustrated by an arrow 9.

In order to realize a particularly advantageous, effective and efficient cooling of the laminated core 4 and thus of the stator 1 and the electric machine 2 as a whole, the respective cooling channel 8 in its circumferential direction completely circulating through the laminated core 4, in particular directly limited. The direct limitation is to be understood that the cooling fluid flowing through the respective cooling channel 8 directly flows or flows around the laminated core 4, in particular respective wall regions of the laminated core 4 bounding the respective cooling channel 8, and thus directly touched. This allows a particularly advantageous heat transfer of the

Laminated core 4 to the respective cooling channel 8 flowing through the cooling fluid.

In FIG. 1, V1 denotes a first variant of the respective cooling channel 8. Furthermore, V2 designates a respective second variant of the respective cooling channel 8, V3 designating a respective third variant of the respective cooling channel 8. The cooling fluid used is preferably a cooling fluid, in particular an oil, in order thereby to be able to remove a particularly large amount of heat from the laminated core 4 in a short time. In one not illustrated in the figures

Embodiment, the respective cooling channel 8 is formed as a cooling tube, wherein the respective cooling channel 8 has an at least substantially circular, can be flowed through by the cooling fluid cross-section.

In the embodiments illustrated in the figures, and in particular in the variants V1, V2 and V3, a slot cooling of the laminated core 4 and thus of the stator 1 is provided. For this purpose, the respective cooling channel 8 is formed as a cooling slot whose cross-section through which the cooling fluid flows has a height H illustrated by the example of the second variant V2 and a width B likewise illustrated by the example of the second variant V2, wherein the width B is substantially greater than the height H is. Preferably, it is provided that the width B is at least 2.5 times larger, in particular at least 3 times larger, and preferably at least 4 times larger than the height H. As a result, a particularly advantageous cooling performance can be represented.

During operation of the electric machine 2, the cooling fluid flows through the respective cooling channel 8 in the axial direction of the stator 1 and thus the electric machine 2 in total, whereby the stator 1 is effectively cooled. The embodiments and variants V1, V2 and V3 shown in the figures as well as the abovementioned embodiment (not shown) can each be used alone or in any desired combination to produce an advantageous embodiment

to realize needs-based cooling.

Trained as a cooling slot cooling channel 8 is in the first variant V1 as

Jochschlitz formed because the cooling channel 8 in the first variant V1 completely in the yoke 5 is located and extends completely in the yoke 5. Thus, the cooling channel 8 is arranged in the first variant V1 without coverage to the grooves 7.

In the second variant V2 exactly one cooling slot is arranged in the respective tooth 6, wherein in the second variant V2 of the cooling slot completely in the tooth

6 is arranged or runs. Thus, the cooling slot in the second variant V2 is completely between the circumferentially immediately consecutive grooves

7 arranged. In the second variant V2, the width B extends at least in the

Substantially in the radial direction of the stator 1 and thus of the tooth 6, in which the cooling slot 6 is arranged. The extending in the radial direction width B is substantially greater than half of the extending in the radial direction extension of the tooth 6, in which the cooling slot is arranged.

In the third variant V3 it is provided that in the respective tooth 6 more of the cooling channels 8, at least partially, in particular in each case at least predominantly or completely, run. In this case, the plurality of cooling channels 8 extending in each case at least partially in the respective tooth 6 are arranged successively or one behind the other in the radial direction of the stator 1. Also in the third variant V3, the respective width B of the respective cooling channel 8 extends at least substantially in the radial direction, wherein the respective width B of the respective cooling channel 8 per se is less than half of the extent of the tooth 6 extending in the radial direction, in FIG which the cooling channels 8 are arranged. However, the sum of the widths B of the cooling channels 8 arranged or extending in the tooth 6 is greater than half of the length or extension, extending in the radial direction, of the tooth 6 in which the plurality of cooling channels 8 are arranged or run. As a result, a particularly advantageous heat dissipation can be realized.

Preferably, the flow of the cooling fluid through the respective cooling channel 8 is at least substantially continuous. For this purpose, at least one or more Kühlmittelverteilringe is provided, for example, the at least one

Kühlmittelverteilring is arranged in the axial direction behind the laminated core 4 or the sheet package 4 anticipates. About the Kühlmittelverteilring the cooling fluid is divided or distributed, for example, on the cooling channels 8. For example, a first of the coolant distribution rings is used to supply the cooling fluid to the cooling channels 8. In this case, the cooling fluid is distributed by means of the first Kühlmittelverteilrings on the cooling channels 8. Further, at least a second of the coolant distribution rings used to collect the cooling fluid flowing from the cooling channels 8 and to discharge accordingly from the cooling channels 8.

Preferably, a flow direction of the cooling fluid is provided in opposite directions parallel to the axial direction of the stator 1, which

For example, in Fig. 2 is illustrated. Fig. 2 shows the stator 1 according to a second embodiment. In the second embodiment, during operation of the electric machine, the cooling fluid flows through those of the cooling passages 8, designated Z in FIG. 2, into a first direction parallel to the axial orientation of the stator 1. Further, the cooling fluid flows during the

Operation of the electric machine 2 by those of the cooling channels 8, which are designated in Fig. 2 with A, in a direction parallel to the axial of the stator 1 and the first direction opposite, the second direction. The first direction is illustrated in FIG. 2 by an arrow 10, wherein the second direction is illustrated by an arrow 11. Thus, for example, a kind of countercurrent cooling can be realized, whereby a particularly effective cooling can be represented.

2, for example, a first side of the stator 1 is denoted by 12, wherein one of the first side opposite second side of the stator 1 is denoted by 13. It is conceivable that the cooling fluid, which also as a cooling medium or

Coolant is referred to, flows in equal parts from the side 12 to the side 13 in the first direction and from the side 13 to the side 12 in the second direction, so that, for example, flowing in the first direction, the total mass flow of the cooling fluid flowing in the second direction Total mass flow of the fluid corresponds.

It is conceivable that the cooling fluid flows through a coolant circuit, which may be configured closed or semi-open. Such a semi-open

Coolant circuit is illustrated in FIG. 2. In this case, a first collecting trough 14 is arranged on the side 12, and on the side 13 a second collecting trough 15 is arranged. By means of the collecting trough 14, for example, the cooling channels A flowing through and on the side 12 from the cooling channels A effluent cooling fluid is collected. By means of the collecting trough 15, for example, the cooling fluid Z and the side 13 flowing out of the cooling channels Z cooling fluid is collected. For example, by means of a conveyor, the collected by means of the collecting tray 14 and thus initially in the sump 14 located cooling fluid from the sump 14 to the and in particular in and through the cooling channels Z and thus from the side 12 to page 13 promoted. Accordingly, it is possible, for example, by means of the conveyor the captured by means of the collecting tray 15 and thus initially in the collecting tray 15 located cooling fluid from the

Drip tray 15 to the and in particular in and through the cooling channels A and thus from the side 13 to the side 12 to promote.

The collected cooling fluid is, for example, in particular before the respective cooling fluid from the respective sump 14 or 15 is again conveyed through the respective cooling channels 8, fed to a heat exchanger, by means of which the cooling fluid is cooled. The heat exchanger comprises, for example, a liquid-air heat exchanger and / or a liquid-liquid heat exchanger. The liquid-air heat exchanger can be flowed through or flowed around by the cooling fluid formed as cooling fluid and by air, so that a heat transfer from the cooling fluid to the air can take place via the fluid-air heat exchanger. As a result, the cooling fluid is cooled.

The liquid-liquid heat exchanger is for example of the

Coolant formed cooling fluid and by another, for example, designed as water coolant flowed through. As a result of a heat transfer via the liquid-liquid heat exchanger from the cooling fluid to the further cooling fluid, the cooling fluid is cooled. Subsequently, the cooling fluid in the manner described, in particular by means of the conveyor, back into the

Cooling channels 8 are introduced or conveyed therethrough. Alternatively, it is conceivable that the cooling fluid flowing out of the respective cooling channels 8 is passed directly via a closed line system, in particular via a closed pipeline system, into a heat exchanger for cooling the cooling fluid and then reintroduced into the stator 1 or into the cooling channels 8, thereby to realize a closed cooling circuit.

3 shows a third embodiment of the stator 1. In the third embodiment, a cooling circuit through which the cooling fluid can flow and is preferably closed is designated by 16. Furthermore, for example, designed as a pump

Conveyor designated 17. By means of the conveyor 17 is the

Cooling fluid through the cooling circuit 16 promoted. The conveyor 17 is

For example via conduit elements, in particular via hoses and / or pipes, fluidly connected to the cooling channels 8, so that by means of the conveyor 17, the cooling fluid can be conveyed through the cooling channels 8. In FIG. 3, arrows illustrate a respective flow direction into which the cooling fluid is conveyed by means of the delivery device 17.

 Furthermore, in the third embodiment, outlet channels 18 are provided, which are preferably fixedly attached to the stator 1 and ensure that the cooling fluid does not pass into an air gap, for example, arranged in the radial direction between the rotor 3 and the stator 1.

Finally, Fig. 4 illustrates a fourth embodiment. FIG. 4 illustrates the above-described flow of the cooling fluid through the respective cooling channels 8. As is illustrated in FIG. 4 by crosses drawn into the cooling channels Z, the cooling fluid flowing through the cooling channels Z flows in the first direction, which runs perpendicular to the image plane of FIG. 4 and into the image plane of FIG. 4. Furthermore, in FIG. 4, points drawn into the cooling channels A illustrate the second direction into which the cooling fluid flowing through the cooling passages A flows. In this case, the second direction is perpendicular to the image plane of Fig. 4 and thereby out of the image plane of Fig. 4 out.

In the fourth embodiment illustrated in FIG. 4, the cooling channels 8 are designed as cooling tubes and each have an at least substantially circular cross-section through which the cooling fluid can flow. Further, the respective cooling channels 8 are arranged in the respective yoke 5. At the fourth

Embodiment, it is provided that the flow direction or flow direction of the cooling fluid is directed alternately from one of the cooling channels 8 to the respective next cooling channel 8. Thus, the cooling fluid flows out of one of the cooling channels 8 and A, for example, and then into one of the cooling channels 8 and Z, respectively.

In particular, for example, the cooling passage Z, into which the cooling fluid flows, in the circumferential direction of the stator 1 directly follows the cooling passage A, from which the cooling fluid has previously flowed out. In other words, it is preferably provided that arranged in the circumferential direction of the stator 1 between each two in the circumferential direction of the stator 1 directly consecutive cooling channels Z exactly a cooling channel A. It is further provided that in the circumferential direction of the stator 1 between each two in the circumferential direction of the stator 1 directly

consecutive cooling channels A exactly one cooling channel Z is arranged. In the described embodiments, a particularly effective cooling of the stator 1 can be realized, so that the space requirement of the stator 1 and thus the electric machine 2 can be kept very low overall. The arrangement of the cooling channels 8 within the laminated core 4, for example, a water jacket surrounding the laminated core 4 can be avoided in a housing of the electric machine 2, so that the electric machine 2 can be designed with particularly small dimensions. This can be a particularly high

Power density can be realized in particular with regard to a continuous power operation. In addition, a particularly efficient cooling system can be realized, so that a particularly high continuous power can be displayed. Thus, it is possible to realize a desired continuous power with a particularly small electric machine, so that a particularly high continuous power density can be displayed.

LIST OF REFERENCE NUMBERS

1 stator

 2 electric machine

3 rotor

 4 laminated core

 5 yoke

 6 tooth

 7 groove

 8 cooling channel

 9 arrow

 10 arrow

 1 1 arrow

 12 page

 13 page

 14 drip tray

 15 drip tray

 16 coolant circuit

17 conveyor

18 outlet trough

 A cooling channel

 B width

 H height

 V1 first variant

 V2 second variant

 V3 third variant

 Z cooling channel

Claims

claims

1 . Stator (1) for an electric machine (2), in particular a motor vehicle, with at least one laminated core (4) in which a plurality of a cooling fluid for cooling the stator (1) and in the axial direction (9) of the stator (1) extending cooling channels (8) is formed, characterized in that

 the respective cooling channel (8) in its circumferential direction is completely circumscribed by the laminated core (4).

2. stator (1) according to claim 1,

 characterized in that

 the respective cooling channel (8) is designed as a cooling slot whose cross-section through which the cooling fluid can flow has a height (H) and a width (B) which is greater than the height (H).

3. stator (1) according to claim 2,

 characterized in that

 the width (B) is at least 2.5 times greater, in particular at least 3 times larger, than the height (H).

4. stator (1) according to one of the preceding claims,

 characterized in that

 the respective cooling channel (8) extends at least over more than half of the axial length (9) of the stator (1) extending length of the laminated core (4).

5. stator (1) according to one of the preceding claims,

 characterized in that

the respective cooling channel (8) extends in the axial direction completely through the laminated core (4).

6. Stator (1) according to one of the preceding claims,

 characterized in that

 the laminated core (4) has a plurality of circumferentially spaced apart the laminated core (4) successive teeth (6) and a plurality of in Umfangsnchtung the laminated core (4) successive, between the teeth (6) arranged grooves (7) for at least partially receiving at least one Winding has.

7. stator (1) according to claim 6,

 characterized in that

 in the respective tooth (6) of at least one of the cooling channels (8) extends at least partially.

8. stator (1) according to claim 7,

 characterized in that

 the at least one cooling channel (8) extends at least predominantly, in particular completely, in the respective tooth (6).

9. stator (1) according to any one of claims 6 to 8,

 characterized in that

 in the respective tooth (6) several of the cooling channels (8) extend at least partially.

10. stator (1) according to claim 9,

 characterized in that

 the plurality, each at least partially in the respective tooth (6)

 extending cooling channels (8) in the radial direction of the stator (1)

are arranged consecutively.

1 1. Stator (1) according to one of the preceding claims,

 characterized in that

 at least one of the cooling channels (8) in a parallel to the axial direction (9) of the stator (1) extending first direction (10) and at least one other of the cooling channels (8) in a direction parallel to the axial direction (9) of the stator (1) extending and the first direction (10) opposite second direction (1 1) can be flowed through by the cooling fluid.

12. Electrical machine (2), in particular for a motor vehicle, with at least one stator (1), which has at least one laminated core (4), in which a plurality of a cooling fluid for cooling the stator (1)

 can be flowed through and in the axial direction of the stator (1) extending cooling channels (8) is formed,

 characterized in that

 the respective cooling channel (8) in its circumferential direction is completely circumscribed by the laminated core (4).