EP3559501A1 - Torsional vibration damping arrangement for the drive train of a vehicle - Google Patents

Abstract

The invention relates to a torsional vibration damping arrangement for the drive train of a vehicle, comprising an input region (50) that is to be driven so as to rotate about an axis of rotation (A) and an output region (55), wherein a first torque transmission path (47) and, parallel thereto, a second torque transmission path (48) are provided between the input region (50) and the output region (55), as well as a coupling arrangement (51), wherein a phase shift arrangement (44) is provided in the first torque transmission path (47), said coupling arrangement (51) being designed as a fluid transmission (60).

Description

 Torsional vibration damping arrangement for the drive train of a vehicle

The present invention relates to a torsional vibration damping arrangement for the drive train of a vehicle, comprising an input range to be driven for rotation about an axis of rotation and an output range, wherein between the input range and the output range a first torque transmission path and parallel thereto a second torque transmission path and a coupling arrangement for superposition of the torque transmission paths are provided, wherein in the first torque transmission path, a phase shifter arrangement for generating a phase shift of guided over the first torque transmission path rotational irregularities with respect to the second torque transmission path guided rotational irregularities is provided.

German Patent Application DE 10 201 1 007 1 18 A1 discloses a torsional vibration damping arrangement which divides the torque introduced into an input region, for example, by a crankshaft of an internal combustion engine, into a torque component transmitted via a first torque transmission path and a torque component conducted via a second torque transmission path. In this torque distribution, not only a static torque is divided, but also the vibrations contained in the torque to be transmitted or rotational irregularities, for example, generated by the periodically occurring ignitions in an internal combustion engine, are proportionally divided between the two torque transmission paths. Here, the coupling arrangement brings the two torque transmission paths together again and introduces the combined total torque into the output region, for example a friction clutch or the like.

In at least one of the torque transmission paths, a phase shifter arrangement is provided, which is constructed in the manner of a vibration damper, that is to say with a primary element and by means of the compressibility of a spring arrangement with respect to this rotatable intermediate element. In particular, when this vibration system is in a supercritical state, that is excited with vibrations exceeding the resonant frequency of the Schwingungssys- tems, a phase shift of up to 180 ° occurs. This means that at maximum phase shift, the vibration components emitted by the vibration system are phase-shifted by 180 ° with respect to the vibration components picked up by the vibration system. Since the vibration components conducted via the other torque transmission path experience no or possibly a different phase shift, the vibration components contained in the merged torque components and then phase-shifted with respect to each other can be destructively superimposed on one another, so that in an ideal case the total torque introduced into the output region has essentially no vibration components contained static torque is. In this case, the coupling arrangement is designed as a planetary gear.

DE 10 201 1 086 982 A1 also discloses a torsional vibration damping arrangement as just described, but here the coupling arrangement is designed as a lever mechanism.

It is the object of the present invention to provide a torsional vibration damping arrangement, which has an improved vibration damping behavior with a simple structure.

According to the invention, this object is achieved by a torsional vibration damping arrangement for a drive train of a vehicle, comprising an input region to be driven for rotation about an axis of rotation (A) and an output region, wherein between the input region and the output region parallel to one another a first torque transmission path for transmitting a first torque component and a second torque transfer path for transmitting a second torque portion of a total torque to be transmitted between the input portion and the output portion, a phase shifter assembly at least in the first torque transmission path, for producing a phase shift of rotational irregularities conducted over the first torque transmission path with respect to rotational nonuniformities directed through the second torque transmission path, the phase shifter assembly a vibration system with a primary element and a comprises a coupling arrangement for combining the first torque component transmitted via the first torque transmission path and the second torque component transmitted via the second torque transmission path and for forwarding the combined torque to the output section the coupling arrangement comprises a first input element connected to the first torque transmission path, a second input element connected to the second torque transmission path and an output element connected to the output range, wherein the coupling arrangement is designed as a fluid transmission. In this case, the fluid transmission comprises at least one housing element, a first cylinder and a second cylinder, both of which are arranged in the housing element and connected to each other by means of a connection opening, and a pair of pistons, comprising a first piston and a second piston, in the respective cylinders of the Housing element by means of an active medium to each other in opposite directions. In this case, one of the two pistons is connected to the output of the phase shifter arrangement and thus represents the first input element of the coupling arrangement, whereas the other of the two pistons is connected to the direct torque transmission path, which thus represents the second input element of the coupling arrangement. The housing element represents the output element of the coupling arrangement and is advantageously connected to the output area, for example to a starting clutch or a transmission. If a torque with torsional vibrations is introduced from the input area, then the torque branches to the first and the second torque transmission path. In the first torque transmission path, the phase shifter arrangement is provided, whereas the second torque transmission path runs directly, ie rigidly from the input side. In the torque transmission from the input region to the output region of the second piston, which is connected to the direct, ie rigid torque transmission path, displaced in the second cylinder of the housing member and exerts a force on its piston surface on the active medium. Since the second cylinder is connected by means of the connection opening with the first cylinder, the active medium exerts a counter-directed force on the surface of the first piston, the one to the second piston performs counter-rotating movement and the vibration system, which consists mainly of springs, biases. If a force equilibrium has been established between the two piston surfaces, a resultant force and thus a resulting torque acting on the output element acts on the output element by means of the housing element, more precisely by means of the cylinder rear walls. Consequently, a static moment is transmitted from the input area to the output area. The dynamic component contained in the static torque, the torsional vibrations are ideally extinguished by swinging the active medium against the vibration system, the spring-mass system, and not transmitted to the output range.

By a ratio of the piston surfaces of the first and second cylinders, a transmission ratio of the coupling arrangement can be adjusted. This type of ratio change is compared to the known in the prior art embodiments, in which the coupling arrangement is designed as a planetary gear or a lever mechanism, implement cost and quickly, since only the effective piston area must be changed.

It may also be advantageous if the cylinders have a curved or straight course in the housing element.

Further, as the active medium, an incompressible medium, such as a hydraulic fluid, an oil or any other known and suitable liquid or a viscous medium can be used.

It may also be advantageous if a plurality of fluid transmission are distributed uniformly or non-uniformly in the circumferential direction about the axis of rotation A.

Also, a gear ratio of the fluid transmission may be determined by a ratio of the piston areas of the first and second pistons.

The present invention will be described below in detail with reference to the accompanying drawings. It shows: Fig. 1 shows the basic principle of a torsional vibration damping arrangement with two parallel torque transmission paths as prior art.

 Fig. 2 shows the basic principle of a torsional vibration damping arrangement with a planetary gear as a coupling arrangement as prior art

Fig. 3 shows a vibration damping arrangement in a linear model with a lever coupling arrangement as prior art

 Fig. 4 - 8 different translations as shown in Fig. 3 as the state of

 technology

 9 shows a vibration damping arrangement according to the invention in a linear model with a fluid transmission as a coupling arrangement

10 shows a sectional view of a torsional vibration damping arrangement according to the invention with a fluid transmission as

 Fig. 1 1 a torsional vibration damping arrangement of Fig. 10 as a plan view in the region of the coupling arrangement.

With reference to FIG. 1, a first embodiment of a torsional vibration damping arrangement, generally designated 10, which operates according to the principle of the torque split-off, will be described below. The torsional vibration damping assembly 10 may be disposed in a driveline, such as a vehicle, between a prime mover and the subsequent portion of the powertrain, such as a transmission, a friction clutch, a hydrodynamic torque converter, or the like.

The torsional vibration damping arrangement 10 shown diagrammatically in FIG. 1 comprises an entrance area, generally designated 50. This input area 50 can be connected, for example, by screwing to a crankshaft, not shown, of a drive unit 61. In the input region 50, the torque absorbed by the drive unit 61 branches into a first torque transmission path 47 and a second torque transmission path 48. In the area of a coupling arrangement, indicated generally at 51, the rotary joints guided via the two torque transmission paths 47, 48 are displaced. momentum parts times and Ma2 again merged into an output torque mouse and then to an output area 55, which may for example be performed as here by a gear 63, forwarded.

In the first torque transmission path 47, a vibration system, generally designated 56, is integrated. The vibration system 56 is effective as a phase shifter assembly 44 and includes a example to be connected to the drive unit primary element 1, and a torque transmitting secondary element 2. Here, the primary element 1 against a damper element assembly 4 to the intermediate mass 5 is relatively rotatable.

From the foregoing description, it can be seen that the vibration system 56 is formed in the manner of a torsional vibration damper with a, as shown here, or a plurality of spring sets 4. By selecting the masses of the primary element 1 and the intermediate mass 5, as well as the stiffness of the spring sets or 4, it is possible to place a resonant frequency of the vibration system 56 in a desired range to a favorable phase shift of torsional vibrations in the first torque transmission path 47 to the To achieve torsional vibrations in the second torque transmission path 48. To achieve this, the first torque transmission path 47 is operated supercritically. At the same time, the oscillation amplitude in the phase-shifted torque transmission path 47 after the spring set 4 decreases. In the second torque transmission path 48, the phase position of the torsional vibrations should be maintained as far as possible. To achieve this, this way is carried out as stiff as possible and with low inertia. The coupling arrangement 51 of the torsional vibration damping arrangement 10 combines the two torque components Mal and Ma 2 again. This is done by the fact that the two torque components Mal and Ma2 and thus the torsional vibration components are superimposed in the form that in an optimal case at a 180 ° phase shift of the two torsional vibration components and the same amplitude of the two torsional vibration components in the two torque transmission paths 47, 48 after the overlay in the coupling arrangement 51 a torque mouse without torsional vibration components is forwarded to the output area 55. Here is a translation of the coupling arrangement, a spring characteristic and an inertia of the intermediate mass 5 are to be chosen so that the amplitude ratios of both torque paths 47; 48 are the same and thus cancel the vibration components each other. The ratio also determines how much torque is passed through the phase-shifted torque transfer path 47 and thus via the spring assembly 4, and how much torque passes through the direct torque transfer path 48.

FIG. 2 shows a standard diagram of the connection of a torsional vibration damping arrangement 10 with two torque transmission paths. Here, the coupling arrangement 51 is designed as a planetary gear 6. In this case, a planetary carrier 8 of the planetary gear 6 is connected in a rotationally fixed manner to the primary element 1. The phase-shifted torque path 47 is connected by means of a drive ring gear 9 with the primary element 1. The drive ring gear 9 meshes with a planetary gear 13, which is rotatably mounted on the planet carrier 8 and thus represents the intermediate mass 5. With the planetary gear 13 is another output side planetary gear 11 rotatably connected. The output-side planetary gear 11 in turn meshes with a driven ring gear 12, wherein the Abtiebshohlrad 12 forms the secondary element 2 and the output member 40 of the coupling assembly 51 represents. In this circuit variant stand ratios greater than 1, 0 to 1, 5 are the most meaningful, since thus a good decoupling result can be achieved. The planet carrier 8 is here in the direct torque transmission path 48.

FIG. 3 shows a vibration damping arrangement in a linear model with a lever coupling arrangement as prior art. For a better understanding, the reference symbols which are also used in a rotational vibration reduction are used here for the explanation, since the function of the elements is comparable. Instead of a torque M in the rotational vibration reduction, a force F is transmitted in the linear vibration reduction. This is intended to explain the different translations of the coupling arrangement 51 as a function of the location of the connection of the output element 40. At the swing transmission damping arrangement with two transmission paths 47; 48 with lever coupling gear are the phase-shifted transmission path 47 which transmits a first force component and the direct transmission path 48, which transmits a second force share, via a coupling element 17 by means of coupling joints 29 hinged and thus transmit a total force Fges from the input area 50 to the output area. The output element 40 of the coupling arrangement 51, which also represents the output of the merged force Faus from the coupling arrangement 51, is also articulated, advantageously by means of a hinge connection 28, connected to the coupling element 17. Depending on a connection position of the output element 40, the translation of the lever coupling mechanism can be divided into the following 5 options, which are shown individually in Figures 4 to 8.

Here, the definition of the translation i has to be specified.

For a rotating system, the gear ratio means:

i = torque at output / torque in phase shift path

For a linear system, the gear ratio means:

i = power at the output / force in the phase shift path

 Here, the angle influences should be neglected. The consideration should apply to small angles.

The following applies to the following transmission ratios.

0 <i <1 means a connection of the output element 40 on the coupling element 17 outside the coupling joints 29 of the direct and indirect transmission path on the side of the phase-shifted transmission path 47. i = 1 means a connection of the output element 40 on the coupling element 17 directly to the coupling joint 29 of the phase-shifted transmission path 47. There is no division of the force or the torque. The entire force or the entire moment is passed over the spring set and is therefore comparable to the rotary system with a known dual mass flywheel. i> 1 means a connection of the output element 40 on the coupling element 17 between the coupling joints 29 of the direct and the phase-shifted transmission path 48; 47. This is the advantageous design range for a known torsional vibration damping arrangement with two torque transmission paths. means a connection of the output element 40 on the coupling element 17 directly to the coupling joint 29 of the direct transmission path 48. There is no division of the transmission path from the input area 50 to the output area 55. The total force Fges or the total torque Mges is passed through the direct transmission path 48. The spring set 4 is thus bridged and turned off. All suggestions are forwarded directly. i <0 means a connection of the output element 40 on the coupling element 17 outside of the coupling joints 29 of the direct and the phase-shifted transmission path on the side of the direct transmission path 48.

By a displacement of the articulated connection of the output element 40 along the coupling element 17 thus a translation of the coupling arrangement 51 can be changed.

 In an ideal interpretation of the translation, the articulated connection of the output member 40 is located in a node.

9 shows a vibration damping arrangement according to the invention in a linear model with a fluid transmission 60 as a coupling arrangement 51 in which a total force Fges via a first transmission path 47 with a first force component and a second transmission path 48 with a second force component Fa2 by means of the fluid transmission as an output force Faus is transmitted to an output element of the fluid transmission 60. The wiring scheme is similar to that of a lever linkage. The coupling of the phase-shifted and the direct transmission path 47; However, 48 takes place here not via a lever or a planetary gear, as known from the prior art, but by an active medium 70, such as a hydraulic fluid 71, as an incompressible medium. The control is effected via a first piston 65, which is connected to the phase-shifted transmission path 47 and which is displaceable in a first cylinder 67 of a housing member 64 and a second piston 66 which is connected to the direct transmission path 48 and in a second cylinder 68 of the housing member 64 is slidable. In this case, the first cylinder is connected to the second cylinder via a connection opening 36. The active medium 70, designed here as hydraulic fluid 71, establishes an operative connection between the two pistons 65 and 66. The housing member 64 is fixedly connected to the output member 40.

 A translation is represented by the ratio of the piston areas AK2 from the direct transmission path 48 to the piston area AK1 from the phase-shifted transmission path 47,

i = 1 + (AK2_direkt / AK1 _phase-shifted) or

i = 1 + | (piston_path_direct / piston_path_phase_shifted) |

In this case, only translations i, according to the above definition, in the range> = 1 can be achieved by adapting the piston surfaces. The basic principle is a hydraulic power transmission. The arrangement of the piston 65; 66 must be such that an opposite movement of the direct 48 and the phase-shifted transmission path 47 takes place. The background is the compression of the spring set 4 by the static force component, in the linear model or by the torque component in the rotary model, and the antiphase oscillatory component of the output signal of the spring assembly 4 with respect to the in-phase component of the direct transmission path 48.

FIG. 10 shows, with FIG. 11, a structural design of a torsional vibration damping arrangement 10 with two torque transmission paths and a fluid transmission 60 as a coupling arrangement 51. In this case, the fluid transmission 60 comprises a hydraulic unit of a first and a second piston 65; 66 in a first and a second cylinder 67; 68 are displaced and executed here by way of example in a curved form.

When applying a torque Mges shifts in the direction of movement rigidly connected to the primary element 1 second piston 66 of the direct torque transmission path 48 in the second cylinder 68 and acts on the piston surface AK2 means of the active medium 70, here the hydraulic fluid 71, on the piston surface AK1 of the first piston 65, by means of a spring set 4 with the Primary element 1 is connected to a force. Due to the inertia of the output member 40, which is on the one hand connected to the housing member 64 and on the other hand, the output of the torsional vibration damping assembly 10 and, for example, with a gear or a starting clutch, both not shown here may be connected, the output member 40 remains in the respective state and is not accelerated. By the force acting on the piston surface AK1 of the first piston, the spring set 4 is compressed. The two pistons 65; 66 are shifted in opposite directions until a force equilibrium or moment equilibrium sets in. At least now, the torque Mges is transmitted via the active medium 70 via a cylinder rear wall 69 to the output element 40 as a mouse. A dynamic vibration component is ideally extinguished by a swinging of the active medium 70, here the hydraulic fluid 71 against the spring-mass system in the phase-shifted torque transmission path 47 and not on the secondary element 2, here the output member 40. The piston seals 75; 76 on the first and second pistons 65; 66 of the phase-shifted and the direct torque transmission path 47; 48 seal the cylinder interior 80 with the active medium 70 from the environment.

Bezuaszeichen

primary element

 secondary element

 Damper element assembly

 spring set

 intermediate mass

 planetary gear

 planet

 drive internal gear

 Torsional vibration damping arrangement output side planetary gear

 output ring

 planet

 coupling element

first input element

 articulation

 coupling joint

second input element

 connecting opening

 output element

 Phase shifter arrangement

first torque transmission path second torque transmission path

entrance area

 coupling arrangement

 output range

 Swing system

 fluid transmission

 power unit

 piston pair

 transmission

housing element 65 first piston

 66 second piston

 67 first cylinder

 68 second cylinder

 69 cylinder rear wall

 70 active medium

 71 hydraulic fluid

 75 piston seal

 76 piston seal

80 cylinder interior

A rotation axis

 AK1 piston area first cylinder AK2 piston area second cylinder d1 diameter first piston d2 diameter second piston Mges total torque

Times torque share 1

Times torque share 2

Mouse output torque Fges total force

Fa1 force share 1

Fa2 force share 2

Faus output power

Claims

claims

1 . A torsional vibration damping arrangement (10) for a drive train of a motor vehicle, comprising an input region (50) to be driven for rotation about an axis of rotation (A) and an output region (55), a first torque transmission path parallel to each other between the input region (50) and the output region (55) (47) for transmitting a first torque portion (times) and a second torque transmission path (48) for transmitting a second torque portion (Ma2) of a between the input portion (50) and the output range (55) to be transmitted total torque (Mges) are provided

 a phase shifter arrangement (44) at least in the first torque transmission path (47) for producing a phase shift of rotational irregularities conducted via the first torque transmission path (47) with respect to rotational irregularities conducted via the second torque transmission path (48), the phase shifter assembly (44) comprising a vibration system (56). with a primary element (1) and against the restoring action of a damper element arrangement (3) with respect to the primary element (1) about the axis of rotation (A) rotatable intermediate mass (5),

 a coupling arrangement (51) for combining the first torque component (Mal) transmitted via the first torque transmission path (47) and the second torque component (Ma2) transmitted via the second torque transmission path (48) and for forwarding the combined torque (mouse) to the output region ( 55), the coupling arrangement (51) having a first input element (20) connected to the first torque transmission path (47), a second input element (30) connected to the second torque transmission path (48) and an output element (40) connected to the Comprises exit area (55),

characterized in that the coupling arrangement (51) is designed as a fluid transmission (60).

Second torsional vibration damping arrangement (10) according to claim 1, characterized in that the fluid transmission (60) comprises at least one pair of pistons (62), a housing element (64) and an active medium (70).

3. A torsional vibration damping arrangement (10) according to claim 2, characterized in that the pair of pistons (62) comprises a first piston (65) and a second piston (66), wherein the housing member (64) comprises a first cylinder (67) and a second cylinder (68), wherein the first cylinder (67) and the second cylinder (68) are interconnected by means of a connection opening (36).

4. torsional vibration damping arrangement (10) according to claim 3, characterized in that the first piston (65) in the first cylinder (67) and the second piston (66) in the second cylinder (68) is slidably disposed, wherein the two pistons ( 65, 66) are in operative connection by means of the active medium (70).

5. torsional vibration damping arrangement (10) according to claim 3 or 4, characterized in that one of the two pistons (65; 66) with the first input element (20) of the coupling arrangement (51) is connected and that the other of the two pistons (66; ) is connected to the second input element (30) of the coupling arrangement (51) and wherein the housing element (64) is connected to the output element (40).

6. torsional vibration damping arrangement (10) according to one of claims 3 to 5, characterized in that at a relative change in position of one of the two pistons (65; 66) to the housing member (64) of the other of the two pistons (66, 65) its position changed in opposite directions.

7. torsional vibration damping arrangement (10) according to one of claims 2 to 6, characterized in that a diameter d1 of the first piston (65) is greater than or equal to or smaller than a diameter d2 of the second piston (66).

8. torsional vibration damping arrangement (10) according to one of claims 3 to 7, characterized in that the first and the second cylinder (67; 68) have a curved course or a straight course.

9. torsional vibration damping arrangement (10) according to one of claims 3 to 7, characterized in that one of the two cylinders (67; 68) has a curved course and the other of the two cylinders (68; 67) has a straight course.

10. torsional vibration damping arrangement (10) according to any one of claims 2 to 9, characterized in that the active medium (70) is an incompressible medium.

1 1. Torsional vibration damping arrangement (10) according to claim 10, characterized in that the incompressible medium is a fluid.

12. torsional vibration damping arrangement (10) according to one of claims 1 to 1 1, characterized in that in the circumferential direction about the axis of rotation (A) two or more fluid transmission (60) are distributed uniformly or non-uniformly.

13. A torsional vibration damping arrangement (10) according to any one of claims 3 to 12, characterized in that a transmission ratio of the coupling arrangement (51) by a ratio of the piston surfaces (AK1, AK2) of the first and the second piston (65; 66) is determined.