WO2024027877A1

WO2024027877A1 - Torsional vibration damper system for a drive train and drive train

Info

Publication number: WO2024027877A1
Application number: PCT/DE2023/100549
Authority: WO
Inventors: Szilard Szikrai; David SCHNÄDELBACH
Original assignee: Schaeffler Technologies AG & Co. KG
Priority date: 2022-08-02
Filing date: 2023-07-26
Publication date: 2024-02-08
Also published as: DE102022119297A1

Abstract

The invention relates to a torsional vibration damper system (1) for a drive train (30) of a hybrid motor vehicle, having: - a damping device (2) for damping torsional vibrations, and - a rotor carrier (3) for an electric machine, which is designed to be connected to a shaft (11) of the torsional vibration damper system (1), - wherein the rotor carrier (3) comprises a shaft connection portion (4) for connecting to a shaft (11) of the torsional vibration damper system (1), - wherein the damping device (2) is non-rotatably connected to the shaft connection portion (2). The invention also relates to a drive train (30) for a hybrid motor vehicle, comprising a torsional vibration damper system (1).

Description

Torsional vibration damper system for a drive train and drive train

The invention relates to a torsional vibration damper system for a drive train of a hybrid motor vehicle and a drive train for a hybrid motor vehicle.

As is known, a drive train 30 for a hybrid motor vehicle has a torsional vibration damper system 1 - see Figures 1 and 2. The torsional vibration damper system 1 dampens vibrations that arise from an internal combustion engine 31 (only indicated with reference numbers).

According to Figures 1 and 2 from the prior art, the torsional vibration damper system 1 for a drive train 30 of a hybrid motor vehicle has a damper device 2 for damping torsional vibrations, and a rotor carrier 3 for an electric machine, which is designed to be connected to a shaft 11.

The rotor carrier 3 includes a shaft connecting section 4 for connecting to the shaft 11 of the torsional vibration damper system 1 and a receiving section 6 for laminated cores and a connecting section 5 for connecting the shaft connecting section 4 to the receiving section 6.

The damper device 2 is connected in a rotationally fixed manner to the receiving section 6 for laminated cores. The non-rotatable connection is realized using screws (see Figures 1 and 2 - Var. I) or rivets (see Figures 1 and 2 - Var. II).

This connection between the damper device 2 and the rotor carrier 3 requires a lot of processing effort on the radially outer edge 3A of the rotor carrier 3. On the one hand, the contact surface of the rotor carrier 3 to the damper device 2 must be machined flat over a large radius and then holes must be made for threads or rivets, and threads may also have to be cut. As a result, a lot of processing effort is required before assembly in order to be able to connect the damper device 2 and the rotor carrier 3 to one another.

It is therefore the object of the present invention to provide a torsional vibration damper system for a drive train of a hybrid motor vehicle as well as a To specify a drive train for a hybrid motor vehicle, which ensures simplified production and assembly and can therefore be produced cost-effectively.

This object is achieved according to the invention by the features of the independent patent claims. Further advantageous developments are the subject of the subclaims.

A first aspect of the present invention includes a torsional vibration damper system for a drive train of a hybrid motor vehicle.

The torsional vibration damper system has a damper device for dampening torsional vibrations and a rotor carrier for an electric machine, which is designed to be connected to a shaft of the torsional vibration damper system.

The rotor carrier includes a shaft connecting section for connection to a shaft of the torsional vibration damper system. Here, the damper device is connected to the shaft connecting section in a rotationally fixed manner. Due to the short radial distance of the shaft connecting section to a rotation axis of the torsional vibration damper system, the processing effort for creating a flat surface for attaching the damper device is reduced in comparison to the prior art - see above. Furthermore, a small number of holes are necessary for connections between the damper device and the shaft connecting section of the rotor carrier due to the smaller radius. This speeds up assembly. However, fewer holes are also necessary because the power is transmitted close to the axis of rotation of the torsional vibration damper system. This improves the flow of power. Furthermore, the torsional vibration damper system can be created in less time compared to solutions from the prior art. With the proposed connection of the shaft connecting section to the damper device, a smaller flat surface can be created as a contact surface on the rotor carrier and fewer holes have to be created for fasteners such as screws or rivets.

The torsional vibration damper system can be designed to be rotatable relative to an axis of rotation. This ensures its rotation. The axis of rotation can be aligned with the same orientation in an axial direction. It can also be provided that the rotor carrier includes a receiving section for laminated cores.

The rotor carrier can also include a connecting section for connecting the shaft connecting section to the receiving section.

Furthermore, the rotor carrier can include a receiving section for laminated cores, wherein the shaft connecting section can include a shaft connecting area for connecting to a shaft of the torsional vibration damper system and a connecting area for connecting to the receiving section.

It is also possible for the rotor carrier to include a receiving section for laminated cores, which is connected to the shaft connecting section. The receiving section for laminated cores can include a receiving area for receiving laminated cores and a connecting area for connecting to the shaft connecting section.

Viewed in the radial direction, the shaft connecting section can have the smallest distance from the axis of rotation and the receiving section for laminated cores can have the largest distance from the axis of rotation.

Viewed in the radial direction, the shaft connecting section can also have a first distance from the axis of rotation and the receiving section for laminated cores can have a second distance from the axis of rotation. The first distance can be smaller or smaller than the second distance.

Furthermore, the connecting section, which connects the shaft connecting section with the receiving section, can have a third distance from the axis of rotation. The third distance can be smaller or smaller than the second distance. The third distance can also be larger than the first distance.

Here, the first, the second and/or the third distance can form the smallest distance of the respective section to the axis of rotation. In other words, the respective distance can be half of the smallest inner diameter of the shaft connecting section, the connecting section or the receiving section. So the first, the second and/or the third distance can form the smallest distance between the axis of rotation and the shaft connecting section, connecting section or receiving section. The damper device can also include a damper input, at least one damper element and a damper output.

The damper input can be connected to the shaft connecting section.

In addition, the damper input can be connected to the shaft connecting section in a rotationally fixed and/or frictional and/or material and/or non-positive manner. At least one screw and/or at least one rivet and/or at least one weld seam, for example produced by laser welding, can connect the damper input to the shaft connecting section. The different connection types meet different requirements for speed, cost and precision.

The damper input can be formed by a hub flange or by a disk or by an annular disk.

The damper input can be arranged centrally within the damper device. Several components of the damper output can also form a kind of casing or receptacle or housing for the damper input.

Furthermore, the damper output can be formed by a driver disk and a counter disk. A spacer plate can be arranged between the driver disk and the counter disk in order to adjust the distance between the driver disk and the counter disk depending on the at least one damper element. Furthermore, the damper input can be arranged between the driver disk and the counter disk.

The damper input can have at least one input device for introducing force onto the at least one damper element. This input device serves to forward the flow of force from the damper input to the at least one damper element or to introduce it into it.

The damper output can also have at least one output device for discharging force from the at least one damper element. This output device serves to forward or divert the power flow from the at least one damper element. In addition, the damper input and/or the damper output can each or together have a receptacle for the at least one damper element or per damper element. Furthermore, a recording can be limited by a driver disk of the damper output and by a counter disk of the damper output. The receptacle can be limited in the circumferential direction or in the tangential direction on the one hand by the input device and on the other hand by the output device. At least one damper element can be arranged in each receptacle. The at least one damper element can thus be arranged with one end on the input device and with its other end on the output device. The at least one damper element thus connects the damper input to the damper output via the input and output device.

Furthermore, it is possible for the at least one damper element to be a spring, e.g. B. is designed as a compression spring.

Furthermore, the torsional vibration damper system can have a shaft as a torque input into the torsional vibration damper system.

The shaft, for example its shaft shoulder or projection, can be connected to the rotor carrier in a rotationally fixed manner. For this purpose, the shaft can be connected to the rotor carrier in a frictional and/or material and/or non-positive manner.

Furthermore, the shaft can have a shaft shoulder or a projection. The projection, for example its outer lateral surface in the radial direction, can be connected to the shaft connecting section in a rotationally fixed manner. The connection can be made, for example, using laser welding. The connection can also be frictional and/or material and/or non-positive with the rotor carrier. The projection can be designed similar to an annular disk when viewed in the axial direction. Thus, the projection protrudes in the radial direction from the shaft surface to generate an exposed connection area for connection to the shaft connection portion of the rotor carrier. This makes it easier to connect the shaft and rotor carrier.

In addition, the torsional vibration damper system can have an output part as a torque output from the torsional vibration damper system. In other words, the output part can have an input into a transmission device, such as. B. form a manual transmission. The output part can be used as a hub, for example one Shaft-hub connection can be formed. The output part and a damper output of the damper device of the torsional vibration damper system can be connected to one another in a frictional and/or material and/or non-positive manner. The output part and a damper output of the damper device of the torsional vibration damper system can also be welded together, e.g. B. by means of a laser, riveted together and / or caulked together.

The output part can be connected in a rotationally fixed manner to a damper output of the damper device. This means that rotational energy can be transferred via the torsional vibration damper system. For this purpose, the output part can be connected to the damper output in a frictional and/or material and/or non-positive manner.

A second aspect of the present invention includes a powertrain for a hybrid motor vehicle.

It is expressly pointed out that the features of the torsional vibration damper system, as mentioned under the first aspect, can be used individually or in combination with one another in the drive train.

A drive train for a hybrid motor vehicle has a torsional vibration damper system according to the first aspect, an electric machine and an internal combustion engine.

The rotor carrier of the torsional vibration damper system can at least partially form a rotor of an electrical machine. The rotor of an electrical machine can include a shaft, for example the shaft of the torsional vibration damper system.

Furthermore, the internal combustion engine can be connected in a rotationally fixed manner to the shaft of the torsional vibration damper system. A connecting part, for example a flexplate, can connect the shaft to the internal combustion engine, wherein the connecting part can be arranged on the shaft using press teeth.

Furthermore, the rotor carrier of the torsional vibration damper system can at least partially form a rotor of an electrical machine. In the event that laminated cores were attached to the receiving section and a shaft and/or a stator were added, the electrical machine would be almost complete. Below, the inventive idea presented above is expressed again and additionally in other words.

This idea concerns - to put it simply - a torsional vibration damper system for a drive train of a hybrid motor vehicle.

A shaft of the torsional vibration damper system can be connected to an internal combustion engine or an internal combustion engine using a so-called flexplate. The flexplate can be pulled onto the shaft with press teeth.

The shaft can be connected to a rotor carrier of the torsional vibration damper system by means of a laser weld on a low or small diameter. More specifically, the shaft may be connected to a shaft connecting portion of the rotor carrier that forms the smallest diameter of the rotor carrier.

A damper device for dampening torsional vibrations can be arranged on the rotor carrier via its hub flange or via its damper inlet. The hub flange and the rotor carrier can be connected to one another in a rotationally fixed manner, for example by means of rivets or screws.

The torque of the internal combustion engine can thus be introduced into the damper device over a small diameter, with the rotor carrier remaining largely unloaded and only being able to be subjected to a boost torque from an electric machine (approx. 20 Nm).

The torque flow continues through the hub flange. Damper elements are actuated due to an input device of the damper input, which serves to introduce force onto compression springs or onto damper elements. As a result, the damper elements act against an output device of a damper output of the damper device, which serves to transfer force from the damper elements or to transmit force.

The damper output can be connected to a hub (e.g. laser welded, could also be riveted or caulked etc.). The torque can be further transferred to a transmission input shaft via the damper output.

The invention is explained in more detail below using exemplary embodiments in conjunction with associated drawings. Show schematically: 1 shows a spatial view of a torsional vibration damper system from the prior art with an enlarged detail in two variants;

FIG. 2 is a sectional view of the torsional vibration damper system from FIG. 1;

3 shows a spatial view of a torsional vibration damper system according to the invention;

4 shows a sectional view of the torsional vibration damper system from FIG. 3 including an enlarged detail;

5 shows an enlarged sectional view of the torsional vibration damper system 1 from FIG. 4; and

6 shows a sectional view of a torsional vibration damper system according to the invention according to a further exemplary embodiment.

In the following description, the same reference numbers are used for the same objects.

Regarding Figures 1 and 2, reference is made to the statements at the beginning of the description, so that further explanations are omitted here.

Figure 3 shows a spatial view of a torsional vibration damper system 1 according to the invention, with Figure 4 showing a sectional view of the torsional vibration damper system from Figure 3 including an enlarged detail.

For the sake of simplicity and brevity, both Figures 3 and 4 will be explained together below.

3 and 4 show a torsional vibration damper system 1 for a drive train 30 of a motor vehicle.

The torsional vibration damper system 1 comprises a damper device 2 for damping torsional vibrations and a rotor carrier 3 for an electrical Machine which is designed to be connected to a shaft 11 of the torsional vibration damper system 1.

The rotor carrier 3 has a shaft connecting section 4 for connection to a shaft 11 of the torsional vibration damper system 1, wherein the damper device 2 is connected to the shaft connecting section 4 in a rotationally fixed manner.

The short or small radial distance of the shaft connecting section 4 to a rotation axis according to Figures 3 and 4 is significantly lower than in Figures 1 and 2.

This is simply due to the smaller radius at which the damper device 2 is connected to the shaft connecting section 4.

Furthermore, a smaller number of holes is necessary for connections between the damper device 2 and the shaft connecting section 4 due to the smaller radius. This speeds up assembly. However, fewer holes are also necessary because the power is transmitted close to the axis of rotation X of the torsional vibration damper system 1. This improves the flow of power.

Furthermore, Figures 3 and 4 show that the damper device 2 comprises a damper input 7, a plurality of damper elements 8 and a damper output 9. The damper input 7 is non-rotatably and non-positively connected to the shaft connecting section 4 of the rotor carrier 3. To do this, several rivets connect the damper input 7 to the shaft connecting section 4.

According to Figures 3 and 4, the damper input 7 is formed by a hub flange or an annular disk and the damper output 9 is formed by a driver disk 15 and a counter disk 16. A spacer plate 17 is arranged between the driver disk 15 and the counter disk 16 in order to adjust the distance between the driver disk 15 and the counter disk 16 depending on the damper elements 8.

The damper input 7 is arranged centrally within the damper device 2. In other words, several components of the damper output, such as driver disk 15 and counter disk 16, form a kind of casing or receptacle Housing for the damper input 7. So the damper input 7 is arranged between the driving disk 15 and the counter disk 16.

Furthermore, the damper input 7 has several input devices (not shown) for introducing force onto the damper elements 8 and the damper output 9 has several output devices (not shown) for transferring force from the damper elements 8.

The damper input 7 and the damper output 9 together form a receptacle 10 per damper element 8, the receptacle 10 being limited in the circumferential direction or tangential direction on the one hand by the input device and on the other hand by the output device. Furthermore, each receptacle 10 is limited by the driving disk 15 and the counter disk 16.

As Figures 3 and 4 indicate, a damper element 8 is arranged in each receptacle 10. Each damper element 8 is arranged with one end on the input device and with its other end on the output device. Looking at Figures 3 and 4 it is clear that the damper elements 8 are designed as springs or as compression springs.

Furthermore, Figure 4 shows, for example, that the rotor carrier 3 includes a receiving section 6 for laminated cores and a connecting section 5 for connecting the shaft connecting section 4 to the receiving section 6.

It can also be seen that the torsional vibration damper system 1 is designed to be rotatable relative to an axis of rotation X.

4 also shows that, viewed in the radial direction R, the shaft connecting section 4 has the smallest distance D1 to the axis of rotation X and the receiving section 6 for laminated cores has the largest distance D2 to the axis of rotation X.

In other words, viewed in the radial direction R, the shaft connecting section 4 has a first distance D1 from the axis of rotation X and the receiving section 6 for laminated cores has a second distance D2 from the axis of rotation

In addition, the connecting section 5, which connects the shaft connecting section 4 to the receiving section 6, has a third distance D3 to the axis of rotation X, where the third distance D3 is less or smaller than the second distance D2. In addition, the second distance D2 is larger than the first distance D1.

The first, second and third distances D1, D2, D3 form the smallest distance of the respective section 3, 4, 5 to the axis of rotation X. In other words, the respective distance D1, D2, D3 corresponds to half of the smallest inner diameter of the shaft connecting section 4 , the connecting section 5 or the receiving section 6. So the first, the second and the third distance D1, D2, D3 form the smallest distance between the axis of rotation X and the shaft connecting section 4, connecting section 5 or receiving section 6.

As already indicated, the torsional vibration damper system 1 has a shaft 11 as a torque input, which, for example its projection 12, is connected to the rotor carrier 3 in a rotationally fixed manner.

The projection 12 of the shaft 11 or its outer lateral surface 13 in the radial direction R is connected to the shaft connecting section 4 in a rotationally fixed manner.

Furthermore, Figures 3 and 4 show that the torsional vibration damper system 1 has an output part 14 as a torque output from the torsional vibration damper system 1. In other words, the output part 14 forms an input into a transmission device (not shown), such as. B. a manual transmission. The output part 14 is designed as a hub, for example a shaft-hub connection.

Furthermore, the output part 14 and the damper output 9 of the damper device 2 of the torsional vibration damper system 1 are welded together, e.g. B. using a laser. So the output part 14 is connected in a rotationally fixed manner to the damper output 9 of the damper device 2 or to its counter disk 16.

In addition, Figures 3 and 4 indicate a drive train 30 for a hybrid motor vehicle.

The drive train 30 includes the torsional vibration damper system 1, an electric machine and an internal combustion engine 31 (indicated only as reference numbers on the right side of the shaft 11).

The internal combustion engine 31 is connected in a rotationally fixed manner to the shaft 11 of the torsional vibration damper system 1, with a connecting part, for example a flex plate (not shown), connecting the shaft 11 to the internal combustion engine 30 can connect. The connecting part can be arranged on the shaft 11 using press teeth.

The rotor carrier 3 of the torsional vibration damper system 1 at least partially forms a rotor of an electrical machine (partly because laminated cores, attached in the receiving section 6, and a stator are missing).

Figure 5 shows an enlarged sectional view of the torsional vibration damper system 1 from Figure 4, with Figure 6 showing a sectional view of a torsional vibration damper system 1 according to the invention according to a further exemplary embodiment.

While Figure 5 shows a more complete picture of Figure 4, Figure 6 differs from Figure 5.

The difference is that in the axial direction A, the depth T1 of the rotor carrier 3 from Figure 5 is greater than the depth T2 of the rotor carrier 3 from Figure 6.

Figures 5 and 6 differ in the axial position of the rotor carrier 3 relative to the shafts 11. This distance is compensated for with the length of the rotor carrier 3 in the axial direction A. The position of the damper device 2 remains the same.

This enables the realization of a modular system, which makes the same side plates (drive plate 15, counter plate 16 and spacer plates 17) possible for several applications. Only the rotor carrier 3 with the corresponding depth T1, T2 has to be selected for the respective application.

Reference character list

1 torsional vibration damper system

Damper device

3 rotor carriers

Shaft connection section

5 connecting section

6 recording section

7 damper input

8 damper element

9 damper output

10 recording

11 rotor shaft

12 lead

13 lateral surface

14 output part

15 driving disk

16 counter disk

17 spacer plate

30 powertrain

31 internal combustion engine

A axial direction

R radial direction

Claims

Patent claims

1 . Torsional vibration damper system (1) for a drive train (30) of a hybrid motor vehicle, comprising:

- a damper device (2) for dampening torsional vibrations, and

- a rotor carrier (3) for an electrical machine, which is designed to be connected to a shaft (11) of the torsional vibration damper system (1),

- wherein the rotor carrier (3) comprises a shaft connecting section (4) for connection to a shaft (11) of the torsional vibration damper system (1), characterized in that

- The damper device (2) is connected to the shaft connecting section (4) in a rotationally fixed manner.

2. Torsional vibration damper system according to claim 1,

- wherein the torsional vibration damper system (1) is designed to be rotatable relative to an axis of rotation (X),

- wherein the rotor carrier (3) comprises a receiving section (6) for laminated cores, and

- where, viewed in the radial direction (R), the shaft connecting section (4) has the smallest distance (D1) from the axis of rotation (X) and the receiving section (6) for laminated cores has the largest distance (D2) from the axis of rotation (X).

3. Torsional vibration damper system according to claim 1 or 2,

- wherein the rotor carrier (3) comprises a receiving section (6) for laminated cores and a connecting section (5) for connecting the shaft connecting section (4) to the receiving section (6),

- where, viewed in the radial direction (R), the shaft connecting section (4) has a first distance (D1) from the axis of rotation (X) and the receiving section (6) for laminated cores has a second distance (D2) from the axis of rotation (X), and wherein the first distance (D1) is less or smaller than the second distance (02). Torsional vibration damper system according to claim 3,

- wherein the connecting section (5), which connects the shaft connecting section (4) to the receiving section (6), has a third distance (D3) from the axis of rotation (X), and

- Wherein the third distance (D3) is less or smaller than the second distance (D2). Torsional vibration damper system according to one of the preceding claims,

- wherein the damper device (2) comprises a damper input (7), at least one damper element (8) and a damper output (9), and

- wherein the damper input (7) is connected to the shaft connecting section (4) in a rotationally fixed and/or frictional and/or material and/or non-positive manner. Torsional vibration damper system according to one of the preceding claims,

- wherein the damper device (2) comprises a damper input (7), at least one damper element (8) and a damper output (9),

- wherein the damper output (9) is formed by a driver disk (15) and a counter disk (16), and

- The damper input (7) being arranged between the driver disk (15) and the counter disk (16). Torsional vibration damper system according to one of the preceding claims,

- wherein the damper input (7) has at least one input device for introducing force onto the at least one damper element (8), and

- wherein the damper output (9) has at least one output device for discharging force from the at least one damper element (8). Torsional vibration damper system according to one of the preceding claims, - wherein the torsional vibration damper system (1) has a shaft (11) as a torque input into the torsional vibration damper system (1),

- wherein the shaft (11) has a projection (12), and

- wherein the projection (12), for example its outer lateral surface (13) in the radial direction (R), is connected in a rotationally fixed manner to the shaft connecting section (4). Torsional vibration damper system according to one of the preceding claims,

- wherein the torsional vibration damper system (1) has an output part (14) as a torque output from the torsional vibration damper system (1), and

- The output part (14) is connected in a rotationally fixed manner to a damper output (9) of the damper device (2). Drive train (30) for a hybrid motor vehicle comprising:

- a torsional vibration damper system (1) according to one of the preceding claims, an electrical machine and an internal combustion engine (31),

- wherein the internal combustion engine (31) is connected in a rotationally fixed manner to the shaft (11) of the torsional vibration damper system (1).