WO2023186210A1 - Stator - Google Patents

Abstract

The invention relates to a stator (1) for an electric machine (2), comprising a stator body (3) with a plurality of stator teeth (4), which are distributed over the circumference of the stator body, and stator slots (5), which are formed between the stator teeth (4) and extend through the stator body (3) in the axial direction, wherein stator windings (6) are arranged in the stator slots (5), and the stator body (3) has an outer lateral surface (7) that is at least partly covered by a sprinkler device (9), which conducts a cooling fluid (8), above the outer lateral surface (7) in the direction of gravity. The sprinkler device (9) has a first cylinder ring segment-shaped shell element (10) which rests against the outer lateral surface (7) with a clearance and which comprises a plurality of outlet openings (11) for the cooling fluid (8) so that the cooling fluid (8) can be applied onto the outer lateral surface (7) of the stator body (3) from the outlet openings (11) in the direction of gravity, and the sprinkler device (9) additionally has a second shell element (12) above the first shell element (8) in the direction of gravity, said second shell element being connected to the first shell element (8), such that an area (13) which guides the cooling fluid (8) that covers the outlet openings (11) is defined between the first shell element (10) and the second shell element (12).

Description

stator

The present invention relates to a stator for an electrical machine, comprising a stator body with a plurality of circumferentially distributed stator teeth and stator slots formed between the stator teeth and extending in the axial direction through the stator body, stator windings being arranged in the stator slots, the stator body having an outer one Has lateral surface, which is at least partially covered in the direction of gravity above the outer lateral surface by a irrigation device carrying a cooling fluid.

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

A detailed description of an electric drive can be found in an article in the magazine ATZ 113th year, 05/2011, pages 360-365 by Erik Schneider, Frank Fickl, Bernd Cebulski and Jens Liebold with the title: Highly integrative 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 which is arranged concentrically and coaxially to a bevel gear differential, with a switchable 2-speed planetary gear set being arranged in the power train between the electric motor and the bevel gear differential, which is also is positioned coaxially to the electric motor or the bevel gear differential or spur gear differential. The drive unit has a very compact design and, thanks to the switchable 2-speed planetary gear set, allows a good compromise between climbing ability, acceleration and energy consumption. Such drive units are also referred to as e-axles or electrically operated drive trains.

In addition to purely electrically operated drive trains, hybrid drive trains are also known. Such drive trains of a hybrid vehicle usually include a combination of an internal combustion engine and a Electric motor, and enable - for example in metropolitan areas - purely electric operation with sufficient range and availability, especially for cross-country journeys. There is also the possibility of being driven simultaneously by the internal combustion engine and the electric motor in certain operating situations.

When developing the electrical machines intended for e-axles or hybrid modules, there is a continuing need to increase their power densities, so that the necessary cooling of the electrical machines is becoming increasingly important. Due to the necessary cooling performance, hydraulic fluids, such as cooling oils, have become established in most concepts for removing heat from the thermally affected areas of an electrical machine.

It is the object of the present invention to provide a stator for an electrical machine which has improved cooling fluid-based cooling.

This object is achieved by a stator for an electrical machine, comprising a stator body with a plurality of circumferentially distributed stator teeth and stator slots formed between the stator teeth and extending in the axial direction through the stator body, stator windings being arranged in the stator slots, the stator body having a has an outer lateral surface, which is covered at least in sections in the direction of gravity above the outer lateral surface by a irrigation device carrying a cooling fluid, the irrigation device having a first cylindrical ring segment-shaped shell element with play on the outer lateral surface and a plurality of outlet openings for the cooling fluid, so that cooling fluid in the direction of gravity can be applied from the outlet openings to the outer lateral surface of the stator body, and the irrigation device further has a second shell element connected in the direction of gravity above the first shell element and connected to the first shell element, so that between the first shell element and the second shell element there is a Space leading to cooling fluid covering outlet openings is defined.

This achieves the advantage that flat cooling of the lateral surface of the stator body is made possible, which is particularly advantageous for stators with a comparatively large axial extent. Such flat cooling of the lateral surface of the stator body can be adjusted, for example, by the gap between the first shell element and the lateral surface of the stator body.

Furthermore, the two-part nature of the irrigation device means it can be manufactured and assembled particularly easily. For example, the irrigation device also allows a leak test of the irrigation device before installation with the stator body, so that possible leaks can be easily discovered during series production.

The two-part irrigation device can be assembled in a particularly simple manner, for example by pushing the already pre-assembled irrigation device from above onto the stator body and then installing the irrigation device with the stator assembly in the motor housing.

The invention can thus contribute to reducing costs, for example by eliminating the need for screwing the two shell elements and resulting optimization of the assembly process, as well as improving the efficiency of the electrical machine through effective stator back cooling. In addition, the risk of leaks can be avoided through a design with comparatively few joints between the shell elements and a leak test before installing the sprinkler system.

The stator according to the invention is preferably designed for use in a radial flux machine. A stator for a radial flux machine is usually cylindrical in design and usually consists of electrical sheets that are electrically insulated from one another and constructed in layers and packaged into laminated cores. Distributed over the circumference, are essentially in the electrical sheet Grooves are arranged parallel to the rotor shaft and accommodate the stator winding or parts of the stator winding.

Stator windings are embedded in the stator slots of the stator according to the invention. A stator winding is an electrically conductive conductor whose length is significantly larger than its diameter. The stator winding can basically have any cross-sectional shape. Rectangular cross-sectional shapes are preferred because they allow high packing and therefore high power densities to be achieved. A stator winding is very particularly preferably made of copper. A stator winding preferably has insulation. To insulate the stator winding, for example, mica paper, which can be reinforced by a glass fabric support for mechanical reasons, can be wound in tape form around one or more stator windings, which are impregnated using a hardening resin. In principle, it is also possible to use a curable lacquer layer without mica paper to insulate a stator winding.

The stator according to the invention also has a stator body. The stator body can be designed in one piece or in several parts, in particular in segments. A one-piece stator body is characterized by the fact that the entire stator body is designed in one piece, viewed circumferentially. The stator body is generally formed from a large number of stacked laminated electrical sheets, each of the electrical sheets being designed to be closed to form a circular ring. A segmented stator body is characterized by the fact that it is made up of individual stator segment parts. The stator body can be constructed from individual stator teeth or stator tooth groups, whereby each individual stator tooth or each individual stator tooth group can be formed from a plurality of stacked laminated electrical sheets, each of the electrical sheets being designed as a stator segment sheet metal part.

The stator body is preferably formed from one or more stator laminated cores. A stator lamination stack is understood to mean a plurality of laminated individual sheets or stator laminations, usually made from electrical steel, which are placed one above the other to form a stack, the so-called stator lamination stack are layered and packaged. The individual sheets can then remain held together in the sheet metal package by gluing, welding or screwing.

The stator teeth of the stator are preferably formed in the stator body. Components of the stator body are referred to as stator teeth, which are designed as parts of the stator body that are circumferentially spaced and directed radially inwards (inner rotor) like teeth and an air gap for the magnetic field is formed between their free ends and a rotor body. The gap existing between the rotor and the stator is called the air gap. In a radial flux machine, this is a substantially circular gap with a radial width that corresponds to the distance between the rotor body and the stator body.

The stator is intended in particular for use in an electric machine within a drive train of a motor vehicle. The electric machine is intended in particular for use within a drive train of a hybrid or fully electric motor vehicle. In particular, the electric machine is dimensioned such that vehicle speeds greater than 50 km/h, preferably greater than 80 km/h and in particular greater than 100 km/h can be achieved. The electric machine particularly preferably has a power greater than 30 kW, preferably greater than 50 kW and in particular greater than 70 kW. It is further preferred that the electric machine provides speeds greater than 5,000 rpm, particularly preferably greater than 10,000 rpm, most preferably greater than 12,500 rpm.

The stator can be accommodated in a motor housing of the electrical machine. A motor housing can in particular be formed from a metallic material. Advantageously, the motor housing can be formed from a metallic cast material, such as cast aluminum, die-cast aluminum, gray cast iron or cast steel. In principle, it is also conceivable to make the motor housing entirely or partially from a plastic. The irrigation device of the stator according to the invention is flowed through by a cooling fluid during operation of the electrical machine. In the electrical machine, the cooling fluid has the function of dissipating heat as efficiently as possible from areas of the electrical machine that are heating up and avoiding undesirable overheating of these areas. In addition to this main task, the cooling fluid can also provide lubrication and corrosion protection for the moving parts and the metal surfaces of the cooling system of the electrical machine. In addition, it can also remove impurities (for example from abrasion), water and air. The hydraulic fluid is preferably a liquid. The cooling fluid can in particular be an oil. In principle, however, it is also conceivable to use aqueous hydraulic fluids, for example emulsions.

According to an advantageous embodiment of the invention, it can be provided that the second shell element has a connection for a hydraulic line for supplying cooling fluid, so that the irrigation device can be connected to a hydraulic circuit of the electrical machine, preferably also having a diaphragm in and / or on the connection is designed to reduce the flow cross section. A further advantage of this design is that the connection of the irrigation device to the cooling fluid circuit can be realized in one of the shell elements, which, for example in combination with a seal, can ensure a liquid-tight main oil circuit up to the aperture under all tolerances. The connection is therefore also suitable for blind installation.

According to a further preferred development of the invention, it can also be provided that the first shell element projects in the axial direction at least on one side beyond the stator body and in the section that projects in the axial direction beyond the stator body has outlet openings, by means of which a winding head located below the outlet openings in the direction of gravity the stator windings can be supplied with cooling fluid. In addition to the cooling of the outer surface of the stator body, this can also provide effective cooling of the winding head, which is subject to high thermal stress, which means that Cooling efficiency for the entire stator is significantly improved. In this context, it is particularly preferred that both winding heads of the stator can be acted upon with a cooling fluid by a section that projects beyond the stator body in the axial direction.

Furthermore, according to a likewise advantageous embodiment of the invention, it can be provided that the first shell element and the second shell element are connected to one another by means of a positive connection, in particular a snap connection, which has proven to be particularly easy to install and safe to install.

According to a further particularly preferred embodiment of the invention, it can be provided that the first shell element and / or the second shell element are / is manufactured by means of a plastic injection molding process, which is particularly favorable from a manufacturing perspective in order to also produce comparatively complex structural designs of the irrigation device cost-effectively to be able to. In addition, a sprinkler system made of plastic can contribute to the lightweight construction of the stator. Of course, it would also be possible to produce a shell element using an additive manufacturing process, such as 3D printing.

Furthermore, the invention can also be further developed in such a way that the second shell element has at least one outlet opening on a section extending in the radial direction, by means of which busbars connected to the winding head can be acted upon with cooling fluid, which also allows the cooling of the electrical machine to be further optimized .

In a likewise preferred embodiment variant of the invention, it can also be provided that the stator body has at least two fastening openings running axially through the stator body and the first shell element has a through opening aligned with a fastening opening at its distal ends in the circumferential direction, the fastening openings and the through openings of each one pen-like Fastening means are penetrated and by means of which the first shell element can be fixed to the stator body and the stator body in a motor housing. In this way it can be achieved that the irrigation device can be fixed relative to the stator body without having to form further constructive measures on the stator body by using the fastening openings that are usually already present in the stator body for this purpose.

It can also be advantageous to further develop the invention in such a way that the outlet openings are arranged along an axially extending straight line, which promotes cooling that is as uniform as possible over the axial extent of the stator body. In this context, it is further preferred that the outlet openings are located on the highest section of the shell element when viewed in the direction of gravity.

According to a further preferred embodiment of the subject matter of the invention, it can be provided that in the section of the first shell element which projects in the axial direction beyond the stator body, an outlet opening is arranged on a section extending in the radial direction, by means of which the busbars connected to the winding head can be acted upon with cooling fluid are, which also contributes to improved cooling of the electrical machine.

Finally, the invention can also be advantageously designed in such a way that the second shell element has two parallel, arcuate channel sections which are hydraulically connected to one another by at least one axially extending channel section. The advantage that results from this is, in particular, that the two winding heads of the stator can be acted upon with cooling fluid via the parallel arcuate channel sections, while the axially extending channel section ensures the cooling of the outer lateral surface of the stator body by applying cooling fluid to the lateral surface .

The invention will be explained in more detail below using figures without restricting the general idea of the invention. It shows:

Figure 1 shows an electrical machine in a schematic cross-sectional view,

Figure 2 shows a stator with a sprinkler device in the unassembled state in a front view,

3 shows a stator with a sprinkler device in the assembled state in a perspective view,

4 shows an electrical machine in a state installed in a motor housing in a front view,

5 shows a stator with a sprinkler device in a schematic axial sectional view,

6 shows a two-part irrigation device in an unassembled and an assembled state, each in a perspective view,

Figure 7 shows a first shell element of the irrigation device in a perspective view,

8 shows a second shell element of the irrigation device in two perspective views,

9 shows a sprinkler device in an axial sectional view,

Figure 10 shows a detailed representation of the irrigation device in a perspective view. 1 shows a stator 1 for an electrical machine 2, comprising a stator body 3 with a plurality of circumferentially distributed stator teeth 4 and stator slots 5 formed between the stator teeth 4 and extending in the axial direction through the stator body 3, with 5 stator windings in the stator slots 6 are arranged. Such a stator 1 is already basically known from the prior art.

2 now shows a stator 1 with an outer lateral surface 7, which is covered at least in sections in the direction of gravity above the outer lateral surface 7 by a sprinkling device 9 carrying a cooling fluid 8. Such a sprinkler device 9 is sometimes also referred to as a stator shower.

As can be seen, for example, from Figure 5, the irrigation device 9 has a first cylindrical segment-shaped shell element 10 which rests with play on the outer lateral surface 7 and has a plurality of outlet openings 11 for the cooling fluid 8, so that cooling fluid 8 flows out of the outlet openings 11 in the direction of gravity onto the outer lateral surface 7 of the stator body 3 can be applied, which is indicated in Figure 5 by the corresponding dashed arrows. The irrigation device 9 also has a second shell element 12 connected in the direction of gravity above the first shell element 10 and to the first shell element 10, so that a space 13 carrying cooling fluid 8 covering the outlet openings 11 is defined between the first shell element 10 and the second shell element 12.

The second shell element 12 also has a connection 14 for a hydraulic line for supplying cooling fluid 8. Since a gap 30 is formed in the radial direction between the first shell element 10 and the lateral surface 7 of the stator body 3, the cooling fluid 8 can be distributed over the lateral surface 7 in the axial and circumferential directions over the stator body 3.

Cooling fluid 8 is introduced into this gap 30 through the outlet openings 11 at the highest point of the stator body 3 in the direction of gravity. The comparatively narrow gap 30 ensures optimal wetting of the outer lateral surface 7 of the stator body 3 with cooling fluid 8 over the entire axial Extension of the stator body 3 can be achieved. The cooling fluid 8 in particular cannot - or at least only with difficulty - flow out of the gap 30 in the axial direction, since the first shell element 10 with its wall sections 32 rests on the end face of the stator body 3 and thus seals it. This results in an axial distribution of cooling fluid 8 within the gap 30, with the main flow direction of the cooling fluid 8 taking place circumferentially over the lateral surface 7 of the stator body 3 in the direction of gravity.

5 it can also be clearly seen that the first shell element 10 projects beyond the stator body 3 in both axial directions and in the sections 15 which project beyond the stator body 3 in the axial direction, outlet openings 16 are formed, by means of which the outlet openings 16 located below the outlet openings 16 in the direction of gravity Winding heads 17 of the stator windings 6 can be acted upon with cooling fluid 8.

A diaphragm 36 is embedded in the hydraulic flow in the hydraulic connection 14 of the second shell element 12. In this way, a further increase in the robustness of the system can be achieved by a potential failure of the positive connection of the two shell elements 10, 12 after the oil volume is throttled by the aperture 36 provided in the connection 14. Such a hydraulic leak would therefore only affect the irrigation device 9 itself and not the entire cooling oil circuit.

Figure 8 shows the second shell element 12, in which two parallel and axially spaced wall sections 34 extending in the radial direction are formed. In the assembled state of the irrigation device 9, the wall sections 34 of the second shell element 12 lie against the corresponding wall sections 31 of the first shell element 10 and thereby seal the irrigation device 9 from the cooling fluid 8. This can be clearly seen from the corresponding synopsis of Figures 5-9.

The shell elements 10, 12 can be assembled into a sprinkler system 9 by pushing the shell elements 10, 12 onto the side. The two Shell elements 10, 12 are clipped together, which can be achieved, for example, by hooks and corresponding openings in the wall sections 31, 34. However, this is not shown in the figures. After the shell elements 10, 12 have been assembled, channels for the cooling fluid 8 then arise within the irrigation device 9, which extend in the circumferential direction along the winding heads 17 and in the axial direction over the stator body 3. As can be seen from the synopsis of Figures 5-9, the negative-positive shape of the two shell elements 10, 12 with a large overlap of the radial wall sections 31, 34 achieves a high level of sealing and easy assembly.

As can be seen from Figures 2-3, the irrigation device 9 is designed so that it can be placed on the back of the stator body 3 from above in the direction of gravity. There can also be positive locking means on the irrigation device 9, by means of which the irrigation device 9 can be fixed in a form-fitting manner relative to the stator body 3, so that, for example, a captive device can be formed during assembly. The irrigation device 9 is then connected to the stator body 3 by the fastening means 22, for example screws. The irrigation device 9 is then inserted together with the stator 1 into the motor housing 24 and fixed there with the fastening means 22.

The two-part nature of the irrigation device can also be clearly explained again with reference to FIG. 6, which shows the two shell elements 10, 12 in an unassembled and assembled state. The first shell element 10 and the second shell element 12 are connected to one another by means of a positive connection, in particular a snap connection, and then form a liquid-tight sprinkler device 9, as shown in the lower image of Figure 6. The first shell element 10 and the second shell element 12 are manufactured using a plastic injection molding process.

From Figure 10 it can be seen that the second shell element 12 has two outlet openings 19 on a section 18 extending in the radial direction, by means of which busbars 20 connected to the winding head 17 are connected Cooling fluid 8 can be acted upon, which can also be clearly seen from a combination of FIG. 3 and FIG. 10.

3 it can be seen in particular that the stator body 3 has at least two fastening openings 23 running axially through the stator body 3 and the first shell element 10 has at its circumferentially distal ends each a through opening 21 aligned with a fastening opening 23, the fastening openings 23 and the through openings 21 are each penetrated by a pin-like fastening means 22 and by means of which the first shell element 10 can be fixed to the stator body 3 and the stator body 3 can be fixed in a motor housing 24. Figure 4 shows the stator body 3 in a corresponding assembled state.

7 shows that the outlet openings 11 of the first shell element 10 are arranged along an axially extending straight line. 7 also shows that in the section 15 of the first shell element 10 which projects in the axial direction beyond the stator body 3, an outlet opening 25 is arranged on a section 26 extending in the radial direction, by means of which the busbars 20 connected to the winding head 17 can be acted upon with cooling fluid 8. As can be seen from the combination with Figure 3 or Figure 4, the busbars 20 are also connected to a control device 29 for energizing the stator winding.

7 also clearly shows that in the sections 15 projecting in the axial direction beyond the stator body 3, a plurality of outlet openings 16 are formed along the circumferential direction of the first shell element 10, by means of which the winding heads located below the outlet openings 16 in the direction of gravity 17 of the stator windings 6 can be acted upon with cooling fluid 8. Cooling of the stator back or the lateral surface 7 as well as the winding heads 17 can thus be provided by the irrigation device 9. The sections 15 which protrude in the axial direction beyond the stator body 3 have wall sections 31 which extend radially in the circumferential direction on their axially outer edge and, parallel to this, an axially spaced wall section 32, so that a trough-like reservoir for the cooling fluid 8 is formed. The trough-like reservoir is delimited in the circumferential direction by the axially and radially extending wall-like sections 26,33. The first shell element 10 is shaped in such a way that it can be manufactured as a plastic injection molded part.

Finally, Figure 8 also shows that the second shell element 12 has two parallel, arcuate channel sections 27, which are hydraulically connected to one another by at least one axially extending channel section 28.

Based on Figure 9 it can also be clearly seen that the potential leakage points 35 are located at the highest points of the channel sections 27, 28 in the direction of gravity. The outlet openings 11, 16 are positioned lower in the direction of gravity so that they would still be supplied with cooling fluid 8 in the event of a leak.

The invention is not limited to the embodiments shown in the figures. The foregoing description is therefore not to be viewed as limiting but rather as illustrative. The following patent claims are to be understood as meaning that a stated feature is present in at least one embodiment of the invention. This does not exclude the presence of other features. If the patent claims and the above description define 'first' and 'second' features, this designation serves to distinguish two similar features without establishing a ranking. Reference character list

1 stator

2 electric machine

3 stator bodies

4 stator teeth

5 stator slots

6 stator windings

7 lateral surface

8 cooling fluid

9 irrigation device

10 shell element

11 exhaust ports

12 shell element

13 room

14 connection

15 section

16 outlet openings

17 winding head

18 section

19 outlet opening

20 power rails

21 passage opening

22 fasteners

23 mounting holes

24 motor housing

25 outlet opening

26 section

27 canal sections

28 canal section

29 control device

30 gaps

31 wall section

32 wall section Section wall section leakage point panel

Claims

Claims stator (1) for an electrical machine

(2), comprising a stator body (3) with a plurality of circumferentially distributed stator teeth (4) and stator slots (5) formed between the stator teeth (4) and extending in the axial direction through the stator body (3), wherein in the stator slots ( 5) stator windings (6) are arranged, the stator body (3) having an outer lateral surface (7) which is covered at least in sections in the direction of gravity above the outer lateral surface (7) by a sprinkling device (9) carrying a cooling fluid (8), characterized in that the irrigation device (9) has a first cylindrical segment-shaped shell element (10) which rests with play on the outer lateral surface (7) and has a plurality of outlet openings (11) for the cooling fluid (8), so that cooling fluid (8) flows out in the direction of gravity the outlet openings (11) can be applied to the outer lateral surface (7) of the stator body (3), and the sprinkling device (9) also has a second shell element (12) connected in the direction of gravity above the first shell element (10) and to the first shell element (10). ), so that a space (13) leading to cooling fluid (8) covering the outlet openings (11) is defined between the first shell element (10) and the second shell element (12). Stator (1) according to claim 1, characterized in that the second shell element (12) has a connection (14) for a hydraulic line for supplying cooling fluid (8), preferably further comprising a diaphragm (36) in and/or on the connection (14) is designed to reduce the flow cross section.

3. Stator (1) according to one of the preceding claims, characterized in that the first shell element (10) projects in the axial direction at least on one side beyond the stator body (3) and in the section (15) projecting in the axial direction beyond the stator body (3). ) Has outlet openings (16), by means of which a winding head (17) of the stator windings (6) located in the direction of gravity below the outlet openings (16) can be acted upon with cooling fluid (8).

4. Stator (1) according to one of the preceding claims, characterized in that the first shell element (10) and the second shell element (12) are connected to one another by means of a positive connection, in particular a snap connection.

5. Stator (1) according to one of the preceding claims, characterized in that the first shell element (10) and / or the second shell element (12) are/is produced by means of a plastic injection molding process.

6. Stator (1) according to one of the preceding claims, characterized in that the second shell element (12) has at least one outlet opening (19) on a section (18) extending in the radial direction, by means of which it is connected to the winding head (17). Busbars (20) can be acted upon with cooling fluid (8).

7. Stator (1) according to one of the preceding claims, characterized in that the stator body (3) has at least two fastening openings (23) extending axially through the stator body (3) and the first shell element (10) at its distal ends in the circumferential direction has a through opening (21) aligned with a fastening opening (23), the fastening openings (23) and the through openings (21) each being penetrated by a pin-like fastening means (22) and by means of this the first shell element (10) can be fixed to the stator body (3) and the stator body (3) can be fixed in a motor housing (24). Stator (1) according to one of the preceding claims, characterized in that the outlet openings (11) are arranged along an axially extending straight line. Stator (1) according to one of the preceding claims, characterized in that in the section (15) of the first shell element (10) which projects in the axial direction beyond the stator body (3), there is an outlet opening (25) on a section (15) which extends in the radial direction ( 26) is arranged, by means of which the busbars (20) connected to the winding head (17) can be acted upon with cooling fluid (8). Stator (1) according to one of the preceding claims, characterized in that the second shell element (12) has two parallel, arcuate channel sections (27), which are hydraulically connected to one another by at least one axially extending channel section (28).