DE102015207769A1 - Electric machine with fluid cooling on the coil winding - Google Patents

Abstract

The present invention relates to an electric machine (01) comprising a stator (02) having a coil winding (03) and a fluid (05) at least partially surrounding the coil winding (03) for receiving during operation of the electrical machine (01) in the Coil winding (03) resulting heat. The electric machine is characterized in particular by a heat dissipation component (08) for removing the heat from the fluid (05).

Description

The invention relates to an electrical machine with a stator comprising a coil winding. Furthermore, the coil winding at least partially surrounding fluid is provided for receiving the generated during operation of the electric machine in the coil winding heat.

For the heat dissipation of electrical machines, the use of cooling jackets is known, in which a coolant is guided. In this case, the heat is dissipated by a mass flow which flows through predetermined channels. The liquid-conducting cooling jacket is usually located on the outer circumference of the stator. In addition, solutions are known in which stator or stator winding are directly surrounded by a cooling medium, such as a dielectric fluid.

The US 2012/269660 shows an electric motor with a stator and a rotor, which are arranged within a housing. Inside the housing is a dielectric fluid. The stator has a winding with an electrical conductor disposed within a ceramic insulating layer. The ceramic insulating layer or conductor is in fluid communication with the dielectric liquid. The dielectric fluid provides thermal and electrical insulation of the electrical conductor, allowing the motor to operate continuously at temperatures in excess of 300 ° C.

In the US 5,682,974 is described by means of an oil cooled motor. Via oil spray nozzles, the stator ends and the stator winding can be sprayed with oil. The oil is fed from a reservoir into channels of the motor housing. To cool the rotor, oil can be introduced into correspondingly arranged channels.

The US 8,680,729 B2 describes a motor with a hermetically sealed housing. In the housing, a stator and a rotor are arranged, which are surrounded by a dielectric cooling liquid.

The EP 1 109 298 A1 shows a cooling apparatus for an electrical machine having means for sealingly insulating the magnetic circuit and the windings of the stator to allow the circulation of a dielectric cooling fluid through the stator and the coil ends.

From the DE 10 2012 221 325 A1 an electric machine for a means of transport is known, which has a stator with a coil winding and at least one winding head. For cooling the coil winding, a first cooling circuit component is used. A second cooling circuit component for cooling the winding head can be connected to the first cooling circuit component. The cooling takes place by means of a cooling liquid. The second cooling circuit component and the winding head are preferably encapsulated in a thermally conductive potting material, whereby a thermal connection of the winding head to the cooling circuit component takes place and heat can be dissipated from the winding head.

In cases where the live conductors are not directly surrounded by a cooling medium, additional thermal resistances exist. As a result, an efficient heat transfer is inhibited. Solutions which have a so-called "wet air gap" - i. a cooling medium is also in the air gap - operated, have the disadvantage that a permanent compatibility of the materials used must be assumed. Furthermore, a reduced performance due to increased friction losses can be expected.

The object of the present invention is to provide an electric machine with efficient cooling. The cooling should require little installation space and be integrated into the electrical machine with little effort.

To achieve the object according to the invention is an electrical machine according to claim 1.

The electric machine according to the invention comprises a stator with a coil winding and a fluid surrounding the coil winding at least partially.

The fluid serves to absorb the heat generated during operation of the electrical machine in the coil winding. It is essential to the invention that the electric machine also has a heat dissipation component for removing the heat from the fluid. In the simplest case can serve as Wärmeabführkomponente the surface of the housing of the electric machine, which is this preferably equipped with appropriate structures, such as ribs or needles, to increase the surface.

A significant advantage of the solution according to the invention is the fact that by using a Wärmeabführkomponente the heat from the coil winding surrounding fluid can be dissipated specifically and with high heat transfer performance. In this way, a very efficient cooling of the coil winding is made possible, because the cooling takes place by means of the fluid on the one hand directly to the heat sources (coil winding), whereby the best possible heat transfer can be realized, and on the other hand, the fluid absorbed heat by the Wärmeabführkomponente be quickly removed from the fluid.

According to an advantageous embodiment, the heat dissipation component comprises channels through which a cooling medium flows. As a result, the fluid can release its heat to the cooling medium in the channels by means of free convection. The channels can be circumferentially introduced into the stator in such a way that they are flowed around by the fluid. Alternatively, the channels can also be arranged circumferentially on the stator. In this case, the channels are thermally conductively connected to the fluid. The second variant has the advantage that in the stator no channels must be introduced and thus no structural modifications to the stator are required.

As low it has proven to provide the stator at its end faces, each with a cup-shaped element for receiving the fluid. The cup-shaped element prevents leakage of fluid. The cup-shaped element can also take over the task of electrical insulation and thus replace the currently commonly used for this purpose insulating paper.

The cooling medium flowed through channels forming the Wärmeabführkomponente are preferably disposed within the cup-shaped element.

According to an advantageous embodiment, a dielectric fluid is used. A dielectric fluid has the advantage that it also acts on the coil winding electrically insulating. The dielectric fluid can thus take over the task of the hitherto used, the coil winding enclosing, insulating potting compound. Although dielectric fluids have low thermal conductivity, the required heat dissipation can be ensured by the difference in temperature between the fluid and the coil winding, usually made of copper. However, it should not be limited to dielectric fluids. When electrically insulated windings are used, electrically conductive liquids may alternatively be used.

The fluid used and its flow path in the stator are preferably chosen so that it allows the removal of heat from the copper coil winding by means of natural convection. Natural convection is known to be due to the temperature difference between the heat source and the heat sink. The known particularly in connection with internal combustion engines Thermosiphonkühlung based for example on natural convection.

To enable a defined flow of the fluid along the coil winding, the use of channel-forming spacers has proven to be expedient. The spacers could for example be introduced directly during the winding process.

According to an advantageous embodiment, the electric machine comprises a pump for generating a circulating fluid flow. This can be cooled by means of forced convection. The spacers additionally serve for insulation between the wires of the coil winding. Without insulation, the wires could touch and the wire insulation itself should provide sufficient insulation.

The fluid may substantially surround the entire coil winding. Alternatively, the fluid can also be guided only around the winding head of the coil winding around and thus act as winding head cooling. Due to the high thermal conductivity of the winding, which generally consists of copper, a winding through the winding head is sufficient in many cases.

In alternative embodiments, the heat dissipation can also be done by means of phase transition. As a result, the heat dissipation can be further improved. The fluid evaporates in this embodiment on the hot coil winding and is then passed to the Wärmeabführkomponente. In the area of the heat dissipation component, condensation takes place due to its lower temperature. Such a circuit, similar to the principle of a heat pipe, could thus be used for heat dissipation.

Preferred embodiments of the invention as well as their advantages and details are explained in more detail below with reference to the attached figures. Show it:

1 a longitudinal sectional view of an electric machine according to the invention;

2 a longitudinal sectional view of a stator of the electric machine according to a first embodiment;

3 a cross-sectional view of the stator according to 2 ;

4 a detail X out 3 in enlarged view;

5 a perspective view of a stator of the electric machine according to a second embodiment.

1 shows a longitudinal sectional view of an electric machine according to the invention 01 , The electric machine 01 includes a stator 02 with a coil winding 03 and a rotor 04 , The stator 03 is in 2 in longitudinal section and in 3 shown in cross section.

The coil winding 03 is at least partially from a fluid 05 (please refer 3 . 4 ) surround. The fluid 05 serves to accommodate during operation of the electric machine 01 in the coil winding 03 resulting heat. 4 can be seen that the flow space for the fluid 05 in the direction of the rotor axis of locking wedges 07 is limited. closing wedges 07 but are not mandatory. The fluid 05 can also through a the fluid 05 bounded in each direction cup-shaped element are limited. In the embodiment shown, the coil winding 03 in an insulating potting compound 06 embedded. However, embodiments are also possible in which the coil winding 03 not from a potting compound 06 is enclosed. When using a dielectric fluid 05 this can simultaneously provide for the electrical insulation. However, it can also be electrically conductive fluids 05 be used. In this case, an electrically insulated coil winding 03 Find use, if on the insulating potting compound 06 should be waived.

Another component of the electric machine 01 is a heat dissipation component, which is in one area 08 can be arranged. By means of the Wärmeabführkomponente the heat from the fluid 05 dissipated. The Wärmeabführkomponente is therefore not directly with the coil winding 03 contacted but via the fluid 05 , The heat dissipation component 08 can on the stator 02 circumferentially arranged channels, which are flowed through by a cooling medium and heat-conducting with the fluid 05 are connected. Favorable, an arrangement of Wärmeabführkomponente has proven in the vicinity of the winding heads to allow the cooling of natural convection. In the area of the heat dissipation component, flow-collecting and flow-distributing modules can also be arranged in order to distribute a volume flow conveyed by a pump. In this case, the heat transfer would take place by forced convection.

Over a cooling jacket 09 In addition, a conventional cooling can take place. On the cooling jacket 09 However, can also be dispensed with, since already achieved by the inventively realized cooling a good cooling effect. Embodiments without cooling jacket 09 have the advantage that they require less space.

5 shows a perspective view of a stator 02 according to a second embodiment. The coil winding 03 surrounding fluid 05 In this embodiment, this is inside sealed cup-shaped elements 10 , which on the front sides of the stator 02 are arranged. Inside the bowl-shaped elements 10 run channels 12 , The channels 12 are flowed through by the cooling medium to dissipate the heat and thus act as Wärmeabführkomponente. The fluid 05 runs between the bowl-shaped elements 10 also in the axial direction. To an escape of fluid 05 from the stator 02 To prevent or prevent a leaky stator surface, this is to be sealed accordingly. The necessary sealing can already by the bias of the stator 02 or mechanically realized in other ways. Alternatively, the stator can also be provided with an impregnation or the shell-shaped elements 10 can be extended to include the fluid 05 completely enclose.

LIST OF REFERENCE NUMBERS

01

 electric machine

02

 stator

03

 coil winding

04

 rotor

05

 fluid

06

 potting compound

07

 closing wedges

08

 Area for heat dissipation component

09

 cooling jacket

10

 cup-shaped element

11

12

 channels

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 2012/269660 [0003]
• US 5682974 [0004]
• US 8680729 B2 [0005]
• EP 1109298 A1 [0006]
• DE 102012221325 A1 [0007]

Claims (10)

Electric machine ( 01 ) comprising a stator ( 02 ) with a coil winding ( 03 ) and a coil winding ( 03 ) at least partially surrounding fluid ( 05 ) for receiving during operation of the electric machine ( 01 ) in the coil winding ( 03 ), characterized in that it further comprises a heat dissipation component ( 08 ) which is in contact with the fluid ( 05 ) is in thermal contact, for removing the heat from the fluid ( 05 ). Electric machine ( 01 ) according to claim 1, characterized in that the heat dissipation component ( 08 ) channels through which a cooling medium flows ( 12 ). Electric machine ( 01 ) according to claim 2, characterized in that the channels ( 12 ) in the stator ( 02 ) and from the fluid ( 05 ) are flowed around. Electric machine ( 01 ) according to claim 2, characterized in that the channels ( 12 ) circumferentially on the outside of the stator ( 02 ) are arranged, wherein the channels ( 12 ) thermally conductive with the fluid ( 05 ) are connected. Electric machine ( 01 ) according to one of claims 1 to 4, characterized in that the stator ( 02 ) at its end faces in each case a cup-shaped element ( 10 ) for receiving the fluid ( 05 ) having. Electric machine ( 01 ) according to claim 5, characterized in that the channels ( 12 ) within the bowl-shaped element ( 10 ) are arranged. Electric machine ( 01 ) according to one of claims 1 to 6, characterized in that a dielectric fluid ( 05 ) is used. Electric machine ( 01 ) according to one of claims 1 to 7, characterized in that on the coil winding ( 03 ) Channel-forming spacers are arranged. Electric machine ( 01 ) according to one of claims 2 to 8, characterized in that it comprises a pump for generating a circulating fluid flow. Electric machine ( 01 ) according to one of claims 1 to 9, characterized in that the fluid ( 05 ) only the winding heads of the coil winding ( 03 ) surrounds.

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