WO2022238041A1 - Bearing arrangement of an electric axle module - Google Patents

Abstract

The invention relates to a bearing arrangement (22) of an electric axle module (10) comprising an electric machine (12) and a transmission (14) having a transmission input shaft (24) that is mounted at multiple points. The bearing arrangement (22) in the transmission (22) is designed as a first x-shaped arrangement (74) of a cover-mounted bearing (30) and a housing-mounted bearing (40). The transmission input shaft (24) has functional diameters (66, 68, 70, 72) that essentially increase from a bearing seat (56) of the cover-mounted bearing (30) in the direction of the center of the transmission input shaft (24). The invention further relates to an electric axle module (10) comprising a bearing arrangement (22) for use in an electrically driven vehicle.

Description

-1

description

title

Bearing arrangement of an E-axis module

technical field

The invention relates to a bearing arrangement of an e-axle module with an electric machine and a transmission and with a transmission input shaft with multiple bearings. Furthermore, the invention relates to the use of the bearing arrangement in the electric drive train of an electrically driven passenger car or an electrically driven commercial vehicle.

State of the art

DE 10 2010048 131 A1 relates to an electric drive unit. This includes a stator and a rotor, a gear and an electrical circuit and a housing. The housing forms an engine compartment in which the electric machine is arranged and a transmission compartment in which at least part of the transmission is arranged. The drive unit has a lubricating circuit, in which a lubricating fluid for lubricating and cooling the rotor of the electrical machine and the transmission is routed, with the lubricating fluid circulating between the motor compartment and the transmission compartment. Furthermore, the drive unit has a cooling circuit, in which a cooling liquid for cooling the stator of the electrical machine and the electrical circuit is routed. The cooling liquid of the cooling circuit is in heat-exchanging connection with the lubricating liquid of the lubricating circuit.

EP 2 846439 A1 relates to an electrical machine with a shaft. The electrical machine includes a rotor which interacts magnetically with the stator when the electrical machine is in operation. Furthermore, a first bearing device and a second bearing device and a shaft 2 provided, which is rotatably mounted in the first bearing device and the second bearing device about an axis of rotation. The shaft has a first portion of a first material and a second portion of a second material sequentially in an axial direction of the axis of rotation, the rotor being fixed to the first portion of the shaft, and the first material and the second material being joined at a joint of the first section and the second section are integrally and homogeneously connected to one another. A shaft is provided for the electric machine including the rotor and a series of electric machines comprising at least one first electric machine and at least one second electric machine, a method for producing an electric machine and a method for producing a series of electric machines.

DE 10350040 A1 relates to a transmission drive unit. The transmission drive unit is used in particular to adjust moving parts in motor vehicles and includes an electric motor which has a rotor arranged inside a stator. Furthermore, a reduction gear arranged coaxially thereto and having a drive shaft is provided, with the rotor being mounted on a hollow shaft, on the outer circumference of which at least one gear component driving the reduction gear is arranged axially next to the rotor and the output shaft penetrating the hollow shaft.

Presentation of the invention

According to the invention, the bearing arrangement of an e-axle module is provided with an electric machine and a transmission as well as with a transmission input shaft with multiple bearings. The bearing arrangement in the transmission is designed as a first X-arrangement of a cover-side bearing and a housing-side bearing, and the transmission input shaft has, starting from a bearing seat of the cover-side bearing, increasing diameters towards the center of the transmission input shaft.

Due to the proposed bearing arrangement of an E-axis module, a rotor pre-assembled on the transmission input shaft can be installed in the assembly direction and - 3 be mounted from the side of the e-axis module in which the electric machine is arranged when the e-axis module is complete. This makes it possible to test the electric machine that has already been assembled, with or without power electronics, before the gearbox is assembled on the e-axis module.

In a further advantageous embodiment of the solution proposed according to the invention, the transmission input shaft is either designed as a one-piece component within the bearing arrangement or alternatively made from several shaft sections made of different materials and joined by friction, laser or capacitor discharge welding.

The bearing arrangement proposed according to the invention for the e-axis module comprises the cover-side bearing, the housing-side bearing and an e-machine bearing. Overall, according to the bearing arrangement proposed according to the invention, the transmission input shaft is rotatably accommodated in three roller bearings. In a further advantageous embodiment of the bearing arrangement proposed according to the invention, the cover-side bearing, the housing-side bearing and the E-machine bearing are designed as radial deep groove ball bearings, as angular contact ball bearings, as cylindrical roller bearings or as tapered roller bearings.

In the bearing arrangement proposed according to the invention, the transmission input shaft has running teeth which are either made directly in the material of the transmission input shaft or which can be joined to the transmission input shaft via splines by means of a pinion.

In an advantageous development of the bearing arrangement proposed according to the invention, the transmission input shaft with the preassembled rotor of the electric machine can be assembled in the assembly direction in a system housing or the E-axis module. This results in a significantly simplified manufacturing process, since the transmission and electric machine can be separated during assembly and these components can be tested.

The inventively proposed bearing assembly is characterized in that the transmission input shaft includes the bearing seat of the cover-side bearing, which is designed in a first diameter and the 4

Transmission input shaft has the running gearing, which is designed with a second diameter that exceeds the first diameter and the transmission input shaft has a bearing seat of the bearing on the housing side, which is designed with a third diameter that exceeds the first and second diameters, and the transmission input shaft has a running surface of a Includes sealing element, the fourth diameter of which exceeds the first, second and third diameters.

Due to the diameter arrangement above, the transmission shaft, whether it is designed in one piece or in several parts, can be joined from one side in the direction of assembly in the E-axis module. This offers advantages in terms of production technology, since the continuous diameter gradation on the transmission-side part of the transmission input shaft allows the rotor to be pre-assembled on the transmission input shaft and test processes that are required during final assembly of the e-axis module can be decoupled from one another.

In a further advantageous embodiment variant of the bearing arrangement proposed according to the invention, axial forces from transmission components of the transmission, which act in the direction of the cover-side bearing, are supported directly or indirectly on the running teeth with the interposition of a sleeve.

Alternatively, there is the possibility that axial forces from transmission components of the transmission, which act in the direction of the cover-side bearing, are supported on an additional shaft shoulder of the transmission input shaft or on a parking lock gear arranged non-rotatably on this.

Furthermore, in the solution proposed according to the invention, it is provided that a parking lock wheel optionally installed on the transmission input shaft is supported directly on the running splines or with the interposition of a sleeve on the running splines or an additional shaft shoulder of the transmission input shaft.

In addition, with regard to the bearing arrangement proposed according to the invention, it should be emphasized that the cover-side bearing and the e-machine bearing of the transmission input shaft form a second X arrangement in the e-axle module. - 5

In addition, the invention relates to the use of the bearing arrangement in the electric drive train of an electrically driven passenger car or an electrically driven commercial vehicle.

Advantages of the Invention

The bearing arrangement proposed according to the invention provides a bearing concept that is very easy to assemble, flexible and robust in terms of its service life. A partial assembly of assemblies is possible, which enables the possibility of component testing when constructing the e-axis module and at the same time represents a highly integrated concept that is very cost-effective, compact and optimized in terms of its weight. The arrangement of the cover-side bearing and the housing-side bearing in the area of the transmission of the E-axis module creates a mounting option that is ideally suited to supporting high gearing forces and a simple position of the preload between the cover-side bearing and the housing-side bearing to allow. The axial forces that occur, generated by the transmission components of the transmission in the E-axis module, which act in the direction of the cover-side bearing, can be supported either directly on the running gear or indirectly via the interposition of a sleeve on the running gear. There is also the option of supporting axial forces acting in the direction of the cover-side bearing on an additional shaft shoulder of the transmission input shaft or on an optionally available parking lock wheel. This in turn can be supported directly on the running gear of the transmission input shaft or with the interposition of a sleeve on the running gear or, for example, on a shaft shoulder additionally formed on the transmission input shaft.

In the case of the bearing arrangement proposed according to the invention, the electric machine bearing has smaller dimensions and is therefore less expensive, since it only serves to absorb the comparatively small forces resulting from the weight of the rotor of the electric machine. 6

Due to the increasing diameters on the transmission input shaft, starting from the cover-side bearing in the direction of the center of the transmission input shaft in the direction of the sealing element, for example a radial sealing ring, it is possible to install the rotor shaft in the E-axis module from the side of the electrical machine. This opens up the possibility of testing an electrical machine that is already mounted on the transmission input shaft, for example the rotor, with or without connection to the power electronics, before the e-axis module is completed by adding the transmission.

In the bearing arrangement proposed according to the invention, roller bearings are preferably used which are designed, for example, as radial deep groove ball bearings, as angular ball bearings, as cylindrical roller bearings or as tapered roller bearings.

The transmission input shaft, which is supported in three ways by the bearing arrangement proposed according to the invention, can be produced in one piece or can be joined from individual shaft sections which are made of different materials. Friction, laser and capacitor discharge welding, for example, can be used to join the shaft sections made from different materials. The design of the transmission input shaft as a multi-part shaft made up of several shaft sections joined together offers the advantage that the most suitable material can be used for the functions, such as running gears and rotor shaft.

Brief description of the drawings

The invention is described in more detail below with reference to the drawings.

Show it:

FIG. 1 shows the components of the bearing arrangement according to the invention, in which the transmission input shaft of an e-axis module is supported in multiple ways, - 7 -

Figure 2 shows the bearing assembly for multiple storage of

Transmission input shaft installed in an e-axle module with transmission and electric machine,

Figure 3 is a schematic representation of the diameter gradation on the transmission input shaft and

FIG. 4 shows a schematic representation of the first X-arrangement in the area of the transmission and the second X-arrangement on the outside of the E-axis module.

Embodiments of the invention

In the following description of the embodiments of the invention, the same or similar elements are denoted by the same reference symbols, with a repeated description of these elements being dispensed with in individual cases. The figures represent the subject matter of the invention only schematically.

Figure 1 shows an embodiment variant of the bearing arrangement 22 proposed according to the invention, for multiple bearing of a transmission input shaft 24 in an E-axis module 10.

The E-axis module 10 according to the schematic representation in Figure 1 includes in addition to the electric machine 12, a transmission 14. The E-axis module 10 includes a system housing 16, which on a transmission side of the E-axis module 10 by a indicated transmission cover 18 is closed. On the opposite side of the e-axis module 10, the system housing 16 is closed, for example, by a gear cover 20 of the electric machine 12. In the bearing arrangement 22 proposed according to the invention according to FIG. 1, the transmission input shaft 24 is mounted in multiple bearings. In the area of the electrical machine 12 of the E-axis module 10, the transmission input shaft 24 comprises a rotor 26 which is surrounded by a stator housing 52 shown in FIG. 2, in which a stator 54 is located. 8th

The illustration according to FIG. 1 shows that the bearing arrangement 22 proposed according to the invention has a bearing 30 on the cover side. The bearing 30 on the cover side can be adjusted with regard to its defined preload, for example by means of a shim washer 28 which is installed in the gear cover 20 . Furthermore, it can be seen from the illustration according to FIG. Running teeth 34 are formed on the transmission input shaft 24 immediately next to the optionally available parking lock wheel 32 . The torque of the electric machine 12 is introduced into the transmission 14 of the E-axis module 10 via this running gear 34 .

The transmission 14 in the E-axis module 10 also includes a bearing 40 on the housing side, the inner ring of which can be fixed in the axial direction on the transmission input shaft 24 with a retaining ring 38 . The bearing 40 on the housing side is mounted in a system housing 16 indicated in FIG. In the immediate vicinity of the bearing 40 on the housing side there is a sealing element 42 which interacts with a running surface which is not shown in detail. This is, for example, a radial shaft seal. The sealing element 42 separates the interior of the electrical machine 12 from the interior of the transmission 14 that is wetted with a lubricant.

Finally, the transmission input shaft 24 is mounted in an electric machine bearing 44 within the framework of the bearing arrangement 22 proposed according to the invention. This has smaller dimensions in comparison to the bearing 30 on the cover side and the bearing 40 on the housing side, since the electric machine bearing 44 on the side of the electric axis module 10 on which the cover 20 is mounted only supports the rotor 26 of the electric machine 12 supports. The forces occurring in the transmission 14 are absorbed by the first-mentioned bearing components, ie the bearing 30 on the cover side and the bearing 40 on the housing side. A wave spring 46 is arranged in the E-machine bearing 44, for example, so that any axial play that occurs in the transmission input shaft 24 can be compensated for. Alternatively, instead of a wave spring 46, a plate spring or a set of plate springs can be used. - 9 -

The transmission input shaft 24 can be made in one piece from a continuous material. In addition, there is the possibility of assembling the transmission input shaft 24, which is mounted several times in the E-axis module 10 in the bearing arrangement 22 proposed according to the invention, from several shaft sections. The individual shaft sections can be made of different materials and can be joined to one another in a materially bonded manner at their joints using materially bonded connection methods, preferably friction welding, laser welding or capacitor discharge welding. The multi-part design of the transmission input shaft 24 has the advantage that, depending on the function of the respective section of the transmission input shaft 24, a material that is optimally suitable for this can be selected.

In the bearing arrangement 22 proposed according to the invention shown in FIG. 1, roller bearings are preferably used as the cover-side bearing 30, the housing-side bearing 40 and the electric machine bearing 44—although this can also be made smaller. These can be radial deep groove ball bearings or angular contact ball bearings,

Cylindrical roller bearings, tapered roller bearings or the like.

The running gearing 34 shown in FIG. 1 can be produced directly in the area of the gearing 14 in the material of the gearing input shaft 24 or it can be shown as a pinion via a spline. In this case, the pinion can be realized as an additional component in the form of a sleeve and have an additional axial fixation. Furthermore, there is the possibility of supporting axial forces on one or both sides via the bearing inner rings of the cover-side bearing 30 and the housing-side bearing 40 .

The illustration according to FIG. 2 shows the E-axis module 10 together with the transmission components 50 and the transmission input shaft 24, which is mounted in multiple bearings in the bearing arrangement 22 proposed according to the invention.

The illustration according to FIG. 2 shows that the torque generated by the electric machine 12 of the E-axis module 10 is transmitted via the running teeth 34 to gear components 50 of the gear 14 that mesh with one another. The rotor 26 of the electric machine 12 rotates within a stator 54 which is accommodated in the stator housing 52 . 10

The cover-side bearing 30 is accommodated on a bearing seat 56 in the area of the transmission cover 18 , while the housing-side bearing 40 of the transmission input shaft 24 is accommodated on a bearing seat 58 of the transmission input shaft 24 . Next to this is a sealing element 42 that can be designed, for example, as a radial shaft sealing ring, which separates the interior of the transmission 14 from the interior of the electric machine 12, so that lubricant circulating in the transmission 14 can be kept away from the interior of the electric machine 12 of the e-axis module 10.

The representation according to FIG. 2 also shows that the electric machine bearing 44 accommodated on a bearing seat 62 of the transmission input shaft 24 is covered and closed off by the cover 20 on the electric axis module 10 .

The representation according to FIG. 3 shows in a schematic manner an embodiment variant of the transmission input shaft 24 to be mounted multiple times in the bearing arrangement 22 proposed according to the invention. Based on the details already described in connection with Figures 1 and 2, the transmission input shaft 24, which is shown in the representation according to Figure 3 in a perspective view and without components arranged on it, is mounted in the mounting direction 64 from the side of the electric machine 12 in the E-axis module 10 installed. In order to enable simple and rapid, at the same time robust and precise assembly, which takes place in the assembly direction 64, the transmission input shaft 24 has individual gradations of functional diameters. These are designed in such a way that, starting from the bearing seat 56, which serves to accommodate the cover-side bearing 30, the functional diameters of the individual components are designed to increase counter to the assembly direction 64. The bearing seat 56 for accommodating the cover-side bearing 30 is designed with a first functional diameter 66 . A second functional diameter 68 of the running gear 34 (addendum circle diameter) adjoining the bearing seat 56 is designed in the second functional diameter 68 which exceeds the first functional diameter 66 of the bearing seat 56 of the transmission input shaft 24 . Furthermore, a third functional diameter 70 is provided, on which the bearing seat 58 for receiving the bearing 40 on the housing side is formed. The largest, fourth function diameter 72 the 11

Transmission input shaft 24 is provided by a running surface 60 for the sealing element 42, which is designed as a radial shaft seal. With regard to the gradation of the functional diameters 66, 68, 70, 72, the fourth functional diameter 72 exceeds the third functional diameter 70, which in turn exceeds the second functional diameter 68, which exceeds the first-mentioned functional diameter 66. This results in an increase in the functional diameters 66, 68, 70, 72, starting from the bearing seat 56 in the direction of the center of the transmission input shaft 24, i. H. in the direction of the running surface 60 of the sealing element 42. The fourth functional diameter 72 is not necessarily the absolutely largest diameter of the transmission input shaft 24; It just has to be larger than all the diameters on the transmission side. The shaft sections of the transmission input shaft 24, which are arranged on the electric machine side, can also have larger diameters. For the sake of completeness, reference is made to the bearing seat 62 which, however, is of secondary importance when the transmission input shaft 24 is assembled in the assembly direction 64 . Between the individual functional diameters 66, 68, 70, 72 described above there can also be shaft sections of the transmission input shaft 24 which have a smaller diameter.

When assembling the transmission input shaft 24 with the shown gradation of the functional diameters 66, 68, 70, 72 in the assembly direction 64 and assembling the rotor 26 of the electrical machine 12 on the circumference of the transmission input shaft 24, such a preassembled unit, whether with or without power electronics, be tested and checked before complete assembly of the e-axis module 10 as shown in FIG. The transmission 14, for example, together with its components 50, can only be completely assembled in a subsequent operation. With regard to the manufacture and testing of the individual components, the transmission 14 and the electric machine 12 of the e-axis module 10, this enables separate testing and testing processes. These can be used by the storage concept proposed according to the invention for multiple storage of the transmission input shaft 24 together with the components accommodated thereon.

It can be seen from the illustration according to FIG. 4 that, with respect to the transmission 14, the cover-side bearing 30 and the housing-side bearing 40 are arranged in a first X-arrangement 74 with respect to one another. In the gearbox area 12

14 occur because of the gear components 50 meshing with one another there, which are generally designed as gearwheels and which are absorbed by the first X-arrangement 74 or by its defined preload. For this purpose, a defined prestressing within the framework of the first X-arrangement 74 of the cover-side bearing 30 and the housing-side bearing 40 can be achieved in an advantageous manner. The preload can be set, for example, by a suitable selection of the shim 28 (cf. illustration according to FIG. 1).

On a larger scale, it should be emphasized that a second X-arrangement 76 on the e-axis module 10 is provided by the cover-side bearing 30 on the one hand and the e-machine bearing 44 on the other. While the cover-side bearing 30 is also part of the first X-arrangement 74, the E-machine bearing 44, which is closed by the cover 20 of the E-axle module 10, is only part of the second X-arrangement 76. In the frame The second X-arrangement 76 is compensated for play by a wave spring 46 shown in FIG. 1, which acts on the E-machine bearing 44 in the axial direction.

In the above-depicted FIGS. 1 to 4, an embodiment variant of the bearing arrangement 22 of an E-axis module 10 proposed according to the invention is described. This is used in the electric drive train of an electrically powered passenger car or an electrically powered commercial vehicle. In addition to the embodiment variant of the bearing arrangement 22 proposed according to the invention for multiple mounting of the transmission input shaft 24 in the housing components 50 of the e-axis module 10, which is illustrated with reference to FIGS the parking lock gear 32 may be present as an option and be attached to the circumference of the transmission input shaft 24 by means of a material bond by means of a weld. Alternatively, there is the possibility of fixing the parking lock wheel 32 in a rotationally fixed manner by means of a spline or by means of the spline 36 on the circumference of the transmission input shaft 24 . The bearing 30 on the cover side and the bearing 40 on the housing side can also be implemented as a fixed-loose bearing, with either the bearing 30 on the cover side or the bearing 40 on the housing side representing the fixed bearing of the fixed-loose bearing. In this case, the floating bearing can also be represented by a spring element or a disk. - 13 -

In a further possible embodiment, a ring can be inserted between the bearing seat 58 and the running surface 60 for the sealing element 42 in the form of a radial shaft sealing ring on the shaft shoulder. This can be supported on the inner ring of the housing-side bearing 40 and the shaft shoulder to the

to increase the contact area. As a result, a necessary jump in diameter on the transmission input shaft 24 in the area of the bearing seat 58 and the running surface 60 for the assembly of the sealing element 42 can be reduced. The edge radii on the inner ring of the bearing 40 on the housing side can be made smaller in order to keep the necessary jump in diameter on the transmission input shaft 24 between the bearing seat 58 on the one hand and the running surface 60 of the sealing element 42 on the other hand as small as possible.

The invention is not limited to the exemplary embodiments described here and the aspects highlighted therein. Rather, within the through the

Claims specified range, a variety of modifications possible, which are within the scope of professional action.

Claims

- 14 - Claims

1. Bearing arrangement (22) of an E-axis module (10) with an electric machine (12) and a transmission (14) and with a transmission input shaft (24) mounted in multiple bearings, characterized in that the bearing arrangement (22) in the transmission ( 14) designed as a first X-arrangement (74) of a cover-side bearing (30) and a housing-side bearing (40) and the transmission input shaft (24), starting from a bearing seat (56) of the cover-side bearing (30), has essentially increasing functional diameters (66, 68, 70, 72) toward the center of the transmission input shaft (24).

2. Bearing arrangement (22) according to claim 1, characterized in that the transmission input shaft (24) is made in one piece or comprises a plurality of shaft sections made from different materials which are joined together by friction, laser or capacitor discharge welding.

3. Bearing arrangement (22) according to claims 1 to 2, characterized in that it comprises the cover-side bearing (30), the housing-side bearing (40) and an E-machine bearing (44).

4. Bearing arrangement (22) according to claims 1 to 3, characterized in that the cover-side bearing (30), the housing-side bearing (40) and the E-machine bearing (44) are designed as radial deep groove ball bearings, angular contact ball bearings, cylindrical roller bearings or as Ball roller bearings are running.

5. Bearing arrangement (22) according to claims 1 to 4, characterized in that the transmission input shaft (24) has running gearing (34) which is embodied in the transmission input shaft (24) or via a shaft-hub connection, in particular a spline , designed as a pinion. - 15 -

6. Bearing arrangement (22) according to claims 1 to 5, characterized in that the transmission input shaft (24) with a preassembled rotor (26) of the electric machine (12) can be mounted in a system housing (16) in the mounting direction (64).

7. Bearing arrangement (22) according to claims 1 to 6, characterized in that the transmission input shaft (24) comprises the bearing seat (56) of the cover-side bearing (30), which is designed in a first functional diameter (66) and also the running teeth ( 34) which is designed in a second functional diameter (68) which exceeds the first functional diameter (66) and has a bearing seat (58) of the housing-side bearing (40) which is designed in a third functional diameter (70) which is the first and second functional diameter (66, 68) and a running surface (60) of the sealing element (42) whose fourth functional diameter (72) exceeds the first, second and third functional diameter (66, 68, 70).

8. Bearing arrangement (22) according to Claims 1 to 7, characterized in that axial forces from gear components (50) of the gear (14), which act in the direction of the cover-side bearing (30), act directly or indirectly on the running teeth (34). support with the interposition of a sleeve.

9. Bearing arrangement (22) according to claims 1 to 7, characterized in that axial forces from gear components (50) of the gear (14), which act in the direction of the cover-side bearing (30), on an additional shaft shoulder of the gear input shaft (24) or on a parking lock wheel (32) arranged directly on this.

10. Bearing arrangement (22) according to claims 1 to 7, characterized in that the parking lock wheel (32) is located directly on the running gear (34) or with the interposition of a sleeve on the running gear (34) or an additional shaft shoulder of the transmission input shaft (24). supports. - 16 - Bearing arrangement (22) according to Claims 1 to 10, characterized in that in the e-axis module (10) the cover-side bearing (30) and the e-machine bearing (44) have a second X-arrangement (76 ) form. Use of the bearing arrangement (22) according to one of Claims 1 to 11 in the electric drive train of an electrically driven passenger car or an electrically driven commercial vehicle.