WO2024109980A1 - Stator - Google Patents

Abstract

The invention relates to a stator (1) of an electric machine (2), in particular for the powertrain (12) of a motor vehicle (13), comprising a stator body (3) with a plurality of stator grooves (4) which extend axially through the stator body (3) and in which a stator winding (5) consisting of a plurality of electric conductors (9) is received, said stator winding exiting at the two end faces (7a, 7b) of the stator body (3), thereby forming a respective winding head (6a, 6b), wherein at least one first conductor pair (13) is made of two electric conductors (9) which exit the stator body (3) at one of the winding heads (6a, 6b) and which are monolithically connected together, and the first conductor pair (13) has a first securing section (10) in the region of the winding head (6a, 6b), said securing section being connected to an HV terminal (11) in an electrically conductive manner in order to energize the stator winding (5).

Description

Stator

The present invention relates to a stator of an electrical machine, in particular for a drive train of a motor vehicle, comprising a stator body with a plurality of stator slots extending axially through the stator body, in which a stator winding consisting of a plurality of electrical conductors is accommodated, which emerges at the two end faces of the stator body to form a winding head in each case.

Electric motors are increasingly being used to power motor vehicles in order to create alternatives to combustion engines that require fossil fuels. Considerable efforts have already been made to improve the suitability of electric drives for everyday use and to offer users the same driving comfort they are used to.

A detailed description of an electric drive can be found in an article in the magazine ATZ, 63rd year, 05/20 6, pages 360-365 by Erik Schneider, Frank Fickl, Bernd Cebulski and Jens Liebold with the title: Highly integrated and flexible electric drive unit for electric vehicles. This article describes a drive unit for an axle of a vehicle, which includes an electric motor that is arranged concentrically to a bevel gear differential. Such drive units are also referred to as electric axles.

In addition to purely electrically operated drive trains, hybrid drive trains are also known. Such drive trains in a hybrid vehicle usually comprise a combination of an internal combustion engine and an electric motor and enable - for example in urban areas - purely electric operation while at the same time providing sufficient range and availability, especially for cross-country journeys. In addition, in certain operating situations it is possible to drive the vehicle simultaneously using the internal combustion engine and the electric motor.

For the development of electrical machines, especially electrical

Machines for the above-mentioned hybrid or fully electric Motor vehicles or wheel hub drives, basically different winding technologies are known for a stator of an electrical machine.

In electrical machines that have a stator with a hollow cylindrical stator, i.e. are designed as an internal rotor machine, and that are configured for use as a traction drive for a motor vehicle, they often have a stator winding with a rectangular cross-section in order to achieve a high power density. In electrical machines that are intended for driving motor vehicles, the stator windings are therefore typically designed as I-pin or hairpin windings. In this case, for example, essentially I- or U-shaped wire segments are introduced into the stator slots from one end face of the stator and then formed on an opposite end face of the stator and connected, for example, by welding.

Such wire segments, which are also referred to as busbars, are either punched from copper sheets or partially formed from rectangular wire. In order to be able to electrically connect the busbars of the stator winding with the busbars of the power electronics, which are also referred to as inverters, an HV terminal is usually positioned in the current flow between the power electronics and one of the winding heads of the stator winding.

It is the object of the invention to provide a stator for an electrical machine which allows particularly simple electrical contact between the stator winding and the inverter of the electrical machine. It is also the object of the invention to produce a stator which can be manufactured particularly cost-effectively.

This object is achieved by a stator of an electrical machine, in particular for a drive train of a motor vehicle, comprising a stator body with a plurality of stator slots extending axially through the stator body, in which a stator winding consisting of a plurality of electrical conductors is accommodated, which, with the formation of each exits from a winding head on the two end faces of the stator body, wherein at least a first conductor pair is formed by two electrical conductors exiting from the stator body at one of the winding heads, which are monolithically connected to one another, wherein the first conductor pair has a first fastening section in the region of the winding head, which is electrically connected to an HV terminal for energizing the stator winding

This has the advantage that additional components for electrically contacting the stator winding with the inverter are not required, which can have a positive effect on ease of assembly and on manufacturing costs. It is also possible to dispense with welding operations for electrical contacting, as the conductor pair is already monolithically formed. This also means that the probability of failure of this electrical contact is significantly lower.

The stator according to the invention is intended for use in an electrical machine. The electrical machine serves to convert electrical energy into mechanical energy and/or vice versa, and it generally comprises the stationary part referred to as the stator, stand or armature and a part referred to as the rotor or runner and arranged to be movable, in particular rotatable, relative to the stationary part. In particular, the electrical machine is dimensioned such that vehicle speeds of greater than 50 km/h, preferably greater than 80 km/h and in particular greater than 100 km/h can be achieved. The electric motor particularly preferably has an output of greater than 30 kW, preferably greater than 50 kW and in particular greater than 70 kW. It is further preferred that the electrical machine provides speeds of greater than 5,000 rpm, particularly preferably greater than 10,000 rpm, very particularly preferably greater than 12,500 rpm.

The stator can be supplied with current in particular by power electronics, which are sometimes also referred to as inverters. The power electronics are preferably a combination of different components which control or regulate a current to the stator, preferably including the peripheral components required for this, such as cooling elements or power supplies. In particular, the power electronics contain one or more several power electronic components which are designed to control or regulate a current. These are particularly preferably one or more power switches, e.g. power transistors. The power electronics particularly preferably have more than two, particularly preferably three separate phases or current paths, each with at least one of its own power electronic component. The power electronics are preferably designed to control or regulate a power with a peak power, preferably continuous power, of at least 10 W, preferably at least 100 W, particularly preferably at least 1000 W per phase. The power electronics are preferably connected to the stator winding of the stator via an HV terminal (HV = high voltage).

For the purposes of this application, motor vehicles are land vehicles that are moved by mechanical power without being tied to railway tracks. A motor vehicle can, for example, be selected from the group of passenger cars (PCs), lorries (HGVs), mopeds, light motor vehicles, motorcycles, buses (KOM) or tractors.

The stator according to the invention can preferably be configured for a radial flux machine. The stator of a radial flux machine is usually cylindrical or cylindrically ring-shaped and generally consists of a stator body which is formed by electrical sheets which are electrically insulated from one another and are layered and packaged to form sheet stacks. This structure keeps the eddy currents in the stator caused by the stator field to a minimum. Stator slots which accommodate the stator winding or parts of the stator winding are distributed over the circumference and arranged parallel to the rotor shaft. Depending on the design towards the surface, the slots can be closed with closure elements such as closure wedges or covers or the like to prevent the stator winding from coming loose.

The stator body is preferably formed in one piece. A one-piece stator body is characterized by the fact that the entire stator body is formed in one piece over its circumference. The stator body is generally formed from a large number of stacked laminated electrical sheets, with each of the electrical sheets is closed to form a circular ring. The individual sheets can be held together in the stator body, for example, by gluing, welding or screwing.

The stator teeth of the stator are preferably formed in the stator body. Stator teeth are components of the stator body that are designed as circumferentially spaced, tooth-like parts of the stator body that are directed radially inwards (inner rotor) or radially outwards (outer rotor), and between their free ends and a rotor body an air gap is formed for the magnetic field and for the rotary movement of the rotor. The air gap is the non-magnetic gap that exists between the rotor and the stator. In a radial flow machine, for example, this is an essentially circular gap with a radial width that corresponds to the distance between the rotor body and the stator body.

A stator winding is embedded in the stator slots of the stator according to the invention. A stator winding comprises electrically conductive conductors whose length is significantly greater than their diameter. The stator winding can basically have any cross-sectional shape. Rectangular cross-sectional shapes are preferred, as they allow high packing and therefore power densities to be achieved. A stator winding is particularly preferably made of copper.

Preferably, the winding is designed as an I-pin or hairpin winding.

According to an advantageous embodiment of the invention, it can be provided that the electrical conductors of the first conductor pair have insulation in the regions in which the electrical conductors run in a stator slot, while the first conductor pair has no insulation in the region of the first fastening section.

The advantage of this design is that it enables immediate electrical contact in the contact area without having to strip the insulation in this area beforehand, which makes installation simplified accordingly. According to a further preferred development of the invention, it can also be provided that the insulation is designed as an insulating varnish.

Furthermore, according to a likewise advantageous embodiment of the invention, it can be provided that the electrical conductors of the stator winding have a substantially rectangular cross-section, which has proven to be advantageous with regard to the required power densities. Furthermore, a rectangular cross-section can promote deformation of the conductor.

According to another particularly preferred embodiment of the invention, it can be provided that the first fastening section is connected directly to the HV terminal, so that no additional component is required for electrical contact.

Furthermore, the invention can also be further developed in such a way that the first fastening section has a ring segment-like shape, whereby in particular a screw connection between the HV terminal and the fastening section can be formed in a particularly advantageous manner. In a preferred embodiment of the invention, it can therefore also be provided that the first fastening section is connected to the HV terminal by means of a screw connection.

It may also be advantageous to further develop the invention in such a way that the first fastening section extends radially outwards from the stator body, whereby the assembly can be simplified since the fastening section can thereby extend in particular radially out of the winding head.

According to a further preferred embodiment of the subject matter of the invention, it can be provided that at least a second conductor pair is formed by two electrical conductors emerging from the stator body at one of the winding heads, which are monolithically connected to one another, wherein the second conductor pair in the region of the winding head has a second Fastening section which is electrically connected to the HV terminal for supplying current to the stator winding. Finally, the invention can also be advantageously designed such that at least a third conductor pair is formed by two electrical conductors which emerge from the stator body at one of the winding heads and are monolithically connected to one another, the third conductor pair having a third fastening section in the region of the winding head which is electrically connected to the HV terminal for supplying current to the stator winding. In this way, three-phase power supply systems for the stator in particular can also be implemented in an assembly-friendly manner.

The invention will be explained in more detail below with reference to figures without limiting the general inventive concept.

It shows:

Figure 1 shows an electrical machine in a schematic axial section,

Figure 2 shows a first cross-sectional view of the electrical machine through the stator body,

Figure 3 shows a second cross-sectional view through the winding head of the electrical machine,

Figure 4 a ladder pair with my fastening section in a top view,

Figure 5 shows a motor vehicle with an electrical machine in a schematic block circuit representation.

Figure 1 shows a stator 1 of an electrical machine 2, in particular for a drive train 12 of a motor vehicle 17, as is also sketched by way of example in Figure 5. A rotor 16 is rotatably mounted to the stator 1. The stator 1 comprises a stator body 3 with a plurality of stator slots 4 extending axially through the stator body 3, in which a stator winding 5 consisting of a plurality of electrical conductors 9 is accommodated, which emerges at the two end faces 7a, 7b of the stator body 3, forming a winding head 6a, 6b, which can be clearly understood from the combination of Figure 2 and Figure 1. In the embodiment shown, the stator winding 5 is designed as an I-pin winding.

As can also be clearly seen from Figure 3, at least a first conductor pair 13 is formed from two electrical conductors 9 which emerge from the stator body 3 at one of the winding heads 6a and are monolithically connected to one another. The first conductor pair 13 has a first fastening section 10 in the area of the winding head 6a, which is electrically connected to an HV terminal 11 for supplying current to the stator winding 5. The first fastening section 10 is connected directly to the HV terminal 11 by means of a screw connection, which engages in a corresponding internal thread 18 on the HV terminal 11 and is thus electrically connected to the HV terminal 11. The first fastening section 10 extends radially outwards from the stator body 3 for this purpose. The HV terminal is supplied with current via the inverter 15.

As can also be clearly seen from Figure 4, a conductor pair 13 is formed from two I-pin-like, rectangular electrical conductors 9, which are connected at a distal longitudinal end by the fastening section 10. To form such a conductor pair 13, an electrical conductor 9 with a rectangular cross-section can be cut to length and stripped at both distal ends and in the middle. It is therefore also clearly visible from Figure 4 that the electrical conductors 9 of the first conductor pair 13 have insulation 14 in the areas in which the electrical conductors 9 run in a stator slot 4, while the first conductor pair 13 has no insulation 14 in the area of the first fastening section 10.

This electrical conductor 9 is then cut into a

ring segment. This creates two essentially parallel extending legs, which form the two I-pins that can be inserted into the stator slots 4 and then twisted so that the interlocking areas 24 shown in Figure 4 are formed on the conductor pair 13. The circular, stripped fastening section 10 forms the opening through which the conductor pair 13 can be screwed to the HV terminal 11. The position of the corresponding screwing point can be ensured by a corresponding bending operation in the lead to the stator slot 4. The fastening section 10 is pivoted radially outwards about the bending edge 19 so that the fastening section 10 protrudes radially from the winding head 6a.

From Figure 3, it can also be clearly seen that a second conductor pair 23 is formed by two electrical conductors 9 which emerge from the stator body 3 at one of the winding heads 6a, 6b and are monolithically connected to one another, wherein the second conductor pair 23 has a second fastening section 20 in the region of the winding head 6a, 6b, which is electrically connected to the HV terminal 11 for supplying current to the stator winding 5.

Furthermore, there is also a third conductor pair 33 of two electrical conductors 9 emerging from the stator body 3 at one of the winding heads 6a, 6b, which are monolithically connected to one another, wherein the third conductor pair 33 has a third fastening section 30 in the region of the winding head 6a, 6b, which is electrically connected to the HV terminal 11 for supplying current to the stator winding 5.

The invention is not limited to the embodiments shown in the figures. The above description is therefore not to be regarded as restrictive, but as explanatory. The following patent claims are to be understood in such a way that a named feature is present in at least one embodiment of the invention. This does not exclude the presence of further features. If the patent claims and the above description define 'first' and 'second' features, this designation serves to distinguish between two similar features without establishing a ranking. List of reference symbols

1 Stator

2 electric machine

3 Stator body

4 stator slots

5 Stator winding

6 Winding head

7 front sides

9 electrical conductors

10 Mounting section

11 HV terminal

12 Drivetrain

13 conductor pair

14 Isolation

15 inverters

16 Rotor

17 Motor vehicle

18 internal thread

19 Bending edge

20 Mounting section

23 conductor pair

24 Entanglement area

30 Mounting section

33 conductor pair

Claims

Expectations

1 . Stator (1) of an electrical machine (2), in particular for a drive train (12) of a motor vehicle (17), comprising a stator body (3) with a plurality of stator slots (4) extending axially through the stator body (3) in which a stator winding (5) consisting of a plurality of electrical conductors (9) is accommodated, which emerges at the two end faces (7a, 7b) of the stator body (3) to form a winding head (6a, 6b), characterized in that at least a first conductor pair (13) is formed by two electrical conductors (9) emerging from the stator body (3) at one of the winding heads (6a, 6b), which are monolithically connected to one another, wherein the first conductor pair (13) has a first fastening section (10) in the region of the winding head (6a, 6b), which is electrically connected to an HV terminal (11) for supplying current to the stator winding (5).

2. Stator (1) according to claim 1, characterized in that the electrical conductors (9) of the first conductor pair (13) have an insulation (14) in the regions in which the electrical conductors (9) run in a stator slot (4), while the first conductor pair (13) has no insulation (14) in the region of the first fastening section (10).

3. Stator (1) according to claim 2, characterized in that the insulation (14) is designed as an insulating varnish.

4. Stator (1) according to one of the preceding claims, characterized in that the electrical conductors (9) of the stator winding (5) have a substantially rectangular cross-section.

5. Stator (1) according to one of the preceding claims, characterized in that the first fastening section (10) is directly connected to the HV terminal (11).

6. Stator (1) according to one of the preceding claims, characterized in that the first fastening section (10) has a ring-segment-like shape.

7. Stator (1) according to one of the preceding claims, characterized in that the first fastening section (10) is connected to the HV terminal (11) by means of a screw connection.

8. Stator (1) according to one of the preceding claims, characterized in that the first fastening section (10) extends in the radial direction outwards from the stator body (3).

9. Stator (1) according to one of the preceding claims, characterized in that at least one second conductor pair (23) of two is arranged on one of the winding heads

(6a, 6b) of electrical conductors (9) emerging from the stator body (3) and which are monolithically connected to one another, wherein the second conductor pair (23) in the region of the winding head (6a, 6b) has a second

fastening section (20) which is electrically connected to the HV terminal (11) for supplying current to the stator winding (5)

10. Stator (1) according to claim 9, characterized in that at least a third conductor pair (33) is formed by two electrical conductors (9) emerging from the stator body (3) at one of the winding heads (6a, 6b), which are monolithically connected to one another, wherein the third conductor Pair (33) in the region of the winding head (6a, 6b) has a third fastening section (30) which is electrically connected to the HV terminal (11) for supplying current to the stator winding (5) 11. Stator (1) according to one of the preceding claims, characterized in that the stator winding (5) is designed as an I-pin winding