DE102007059366A1 - Drive train, particularly motor vehicle drive train, has rigid coupling between two sides operated above marginal torque, which is larger than reaction torque of power engine and smaller than maximum torque of prime mover - Google Patents

Abstract

The drive train has a prime mover (1) for feeding drive power into the drive train. A torsional vibration damper (3) has spring characteristic providing the liquid or the gas by spring element. A damping of relative torsion is operated either sides (4,5) below a marginal torque applied on the primary side (4) or secondary side (5). A rigid coupling in direction of rotation between the two sides is operated with or above the marginal torque. The marginal torque is larger than the reaction torque of power engine (2) and smaller than the maximum value of the torque of the prime mover.

Description

The The invention relates to a drive train, in particular a motor vehicle drive train, by means which transmitted from a prime mover drive power to an aggregate is, wherein the aggregate in particular a so-called accessory a motor vehicle drive train is.

In known powertrains, as for example in the published patent application DE 10 2005 055 795 A1 described, the features known from this document are summarized in the preamble of claim 1, torsional vibration dampers are provided for damping torsional vibrations. These torsional vibration dampers are arranged by suitable damping means such that they reliably provide a damping effect in any physically possible operating state of the drive train. For this purpose, the torque-dependent damping region is provided, in particular, by different damping means connected in series with respect to their effect in order to ensure that in no operating state a rigid mechanical coupling occurs between the primary side and the secondary side of the damper.

Even though the known dampers with a very large damping range Used successfully in various powertrains However, the use of these dampers always means a certain loss of efficiency in the drive power transmission in the powertrain, which is due to friction or other dissipation is. Since the known damper, as shown, the entire maximum can transmit torque occurring in the drive train Furthermore, the dampers are comparatively solid with relatively large dimensions.

Of the present invention is based on the object, a drive train to present with a vibration damper that respects its efficiency in the drive power transmission from a prime mover to an aggregate, in particular ancillary unit, is improved.

The The object of the invention is achieved by a drive train solved with the features of claim 1. In the dependent Claims are advantageous and particularly expedient Embodiments of the invention indicated.

One Drive train according to the invention has an engine for feeding drive power into the drive train. The Drive machine, in particular as an internal combustion engine, for example as a diesel engine or other piston engine, is set up, can a torque between a predetermined minimum value and a predetermined one Feed maximum value into the drivetrain, whereby that of the Drive machine in particular fed into the drive train torque value depends on the speed of the prime mover, with which she is currently working.

The Aggregate in the drive train according to the invention, which is driven by means of the drive machine, has at least two operating states, namely a switched on State in which it generates a first reaction torque, which is from the engine must be overcome, and one switched off state in which there is a second reaction moment generated, which are overcome by the prime mover must, with the second reaction moment smaller or essential is less than the first reaction moment. In particular, that is second reaction moment up to 50, 30, 20 or 10 percent of the first Reaction torque. For example, if the driven unit is is an electrical unit, so corresponds to the switched State a powered state and the off state a state in which the power supply for the electric Aggregate is switched off.

The Aggregate can also be switched on and off by the Drive connection between the prime mover and the unit in the "switched on" Condition produced and physically in the "off" state is interrupted, for example by means of a separating clutch in the drive connection between the prime mover and the unit. In this case, the second to be overcome by the prime mover Reaction torque a moment of zero or to view the torque which is necessary to drive connection up to the place to drive the interruption, that is, for example Waves and cogs moving in the direction of power flow are provided before the interruption.

In the drive connection between the prime mover and driven by the engine or optionally driven unit according to the invention a torsional vibration damper is arranged, which has a primary side and a secondary side, which are rotatable in the circumferential direction limited relative to each other and a spring element, a damping fluid, a damping gas or the like are supported against each other for producing a damping. Additionally or alternatively, it is also possible to support the primary side and the secondary side against one another via a rubbing support against one another or via a mechanically rubbing engagement with one another. So with at least one friction element may be provided, which is arranged between the two sides as an independent component, in particular is positively or non-positively connected to one of the two sides, or which is integrated in one of the two sides. Of course, both sides can be provided with one or more friction elements.

According to the invention now the torsional vibration damper on such a spring characteristic, which by the spring element, the liquid or the Gas, which / which is used for damping, conditionally is that below a predetermined limit torque, which on the primary side of the torsional vibration damper is applied and which transferred to the secondary side is, the relative rotation of both sides - primary side and secondary side - mutually attenuated is, and at or above the limit torque, that on the primary side is applied, a rigid coupling in the direction of rotation of the torsional vibration damper between the primary side and the secondary side will be produced. This limit torque, which is the working area the damper thus in a muted area and subdivided an undamped (rigid) area, is greater than the second reaction moment of the aggregate, that is Reaction torque of the unit in the off / decoupled State, and at the same time smaller than the maximum value of the torque the prime mover.

Especially This limiting torque of the torsional vibration damper is advantageous at the same time smaller than the first reaction moment of the aggregate, the means less than the torque generated by the unit in the switched on or switched state on the Powertrain is exercised. Thus it can be achieved that whenever the unit is driven by the prime mover powered switched or switched state is, the torsional vibration damper no damping exercise and mechanically bridged, so to speak is, and whenever the unit is off or the drive connection is interrupted to the unit, a torsional vibration damping caused by the torsional vibration damper. hereby can make noise and unwanted vibrations be avoided, which conventionally by a respect the rotational position indeterminate state of the accessory or the broken drive train assigned to it emerged.

Especially Advantageously, the limit torque of the torsional vibration damper, which the damping area and the non-damping Range separates, less than 50 percent, less than 30 percent or less than 20 percent of the maximum torque of the prime mover. In practice, it has turned out that 10 to 15 percent of Maximum value of the torque of the prime mover for the limit torque is often sufficient.

Especially Advantageously, the aggregate is a so-called Auxiliary unit, in particular in a vehicle drive train. Such a Powertrain then has a main branch over which a main unit or - in a vehicle drive train - drive wheels of the vehicle can be driven by means of the drive machine. By doing Main line can be provided, for example, a manual transmission, to different translations between the speed of the Drive machine and the speed of the main unit or To produce the speed of the drive wheels.

in the Main branch is a power split provided to drive power decouple from the main branch and feed it into a side branch, wherein in this secondary branch, the unit is arranged. The power split is in particular - in the direction of power flow in traction operation seen - arranged in front of said transmission. The inventively designed torsional vibration damper can then either directly in the power split or be arranged in the secondary branch.

in the Main branch can additionally a second torsional vibration damper be provided, which then usually torsional vibrations in the entire torque range the prime mover up to their maximum value of the torque attenuates.

The Invention will be described below with reference to an embodiment and the attached figure exemplified become.

In the 1 One recognizes a motor vehicle drive train with a prime mover 1 , by means of which the drive wheels 11 the vehicle are driven. The drive of the wheels 11 takes place via a main branch 7 of the drive train. In the main branch 7 are seen in the direction of the power flow in traction operation successively arranged the following components:
the output shaft 12 the prime mover 1 , a hydrodynamic starting element, here in the form of a hydrodynamic converter 13 , by means of a clutch, here a multi-plate clutch 14 , can be mechanically bridged, a manual transmission input shaft 15 , a manual transmission 8th , a gearbox output shaft 16 , a differential 17 , Drive shafts 18 and finally the drive wheels 11 , Under gearbox is any device to understand, by means of which optionally different Translations the Drehzahlbeziehungsweise torque conversion can be adjusted, such as a manual transmission, an automatic transmission or an automatic transmission.

On the power transmission in the region of the hydrodynamic starting element or the hydrodynamic converter 13 will be discussed in more detail below. As you can see, the output shaft is 12 the prime mover 1 mechanically with the impeller 13.1 connected and at the same time with the first coupling half 14.1 the multi-plate clutch 14 , Thus, drive power of the prime mover 1 either via the working medium circuit in the working space of the hydrodynamic converter 13 hydrodynamically from the impeller 13.1 on the turbine wheel 13.2 and then mechanically to the transmission input shaft 15 be transferred, or mechanically from the first coupling half 14.1 on the second coupling half 14.2 the multi-plate clutch 14 and then on the manual transmission input shaft 15 , In the former case, a torsional vibration damping via the hydrodynamic converter 13 causes. In the second case, a torsional vibration damping via the torsional vibration damper 10 in the main branch 7 causes. As you can see, this torsional vibration damper 10 in the direction of the drive power flow in traction behind the multi-plate clutch 14 and in front of the manual transmission input shaft 15 arranged.

Of course, it is also possible to use a different mechanical lock-up clutch than the multi-plate clutch 14 to provide or the torsional vibration damper 10 in the main branch 7 to position at another location, for example in the direction of traction power flow in traction behind the turbine 13.2 or between the turbine wheel 13.2 and the manual transmission 8th , Then would also be in the operating state with hydrodynamic power transmission through the converter 13 additionally a torsional vibration damping by means of the torsional vibration damper 10 be achieved. Further positions for the torsional vibration damper 10 in the main branch 7 are possible.

Instead of the hydrodynamic converter 13 could, for example, a hydrodynamic coupling, which then in contrast to the hydrodynamic converter shown 13 no stator 13.3 or another starting element, for example a mechanical friction element or a viscous coupling can be provided.

The main branch 7 of the drive train has a power split, in the embodiment shown by the hydrodynamic converter 13 is formed. That's the impeller 13.1 connected to a so-called power take-off, via which drive power from the main branch 7 in a side branch 9 is branched off. In the embodiment shown, the power take-off is by a pair of spur gears 19 . 20 formed, with the spur gear 19 in a drive connection with the impeller 13.1 stands, and in particular is supported by this, and the spur gear 20 from a power take-off shaft 21 will be carried. Other drive connections are possible.

In the spur gear 19 and thus in the secondary branch 9 is a torsional vibration damper 3 integrated, comprising a primary page 4 and a secondary side 5 , The secondary side 5 is via a spring element 6 limited in the circumferential direction rotatable relative to the primary side 4 on the primary side 4 supported. On its outer circumference or in the region of its outer circumference carries the torsional vibration damper 3 an external toothing to the first spur gear 19 train.

The PTO shaft 21 stands over a separating clutch 22 in a drive connection with an aggregate 2 , Which in the present case is therefore designed as a so-called auxiliary unit. Thus, the aggregate 2 optionally via the separating clutch 22 in a drive connection with the prime mover 1 and be switched out of this.

The torsional vibration damper 3 in the secondary branch 9 has the following task:
Always when the disconnect clutch 22 is opened, is about the power take-off, that is, the spur gears 20 and 19 , a very small reaction moment, so to speak, backwards into the main branch 7 fed. This has traditionally resulted in indeterminate conditions that lead to undesirable vibrations and noises. The provision of the torsional vibration damper 3 in the secondary branch 9 is used exclusively for damping these vibrations during idling operation of the auxiliary unit 2 if this, as in the embodiment shown by means of the separating clutch 22 is switched out of the drive connection or instead of being separated out of the drive train by means of a disconnect clutch, idles load-free or substantially free of load. In rated operation of the unit 2 however, the torsional vibration damper should 3 for efficiency reasons, no vibration damping effect in the secondary branch 9 produce.

According to the invention, the torsional vibration damper 3 Therefore, designed with such a spring characteristic that in the rated operation of the unit 2 the primary side 4 and the secondary side 5 mechanically or rigidly coupled to each other, at least in the direction of rotation of the two sides 4 . 5 , This can be achieved, for example, in that the spring element 6 maximum einfedert and yourself the primary side 4 thus rigid, without a damping on the secondary side 5 supports and drives them. Idling the unit 2 or in load-free operation of the unit 2 however, the torsional vibration damper works 3 in the damping region, that is, the spring element 6 dampens torsional vibrations by more or less strong compression.

According to an advantageous embodiment of the torsional vibration damper is designed such that a mechanical abutment within the spring element, in wound compression springs of the individual spring coils together, is prevented. This striking of the individual spring coils is also referred to as "going to block." In order to avoid such a stop within the spring element, for example, a mechanical stop between the primary side 4 and the secondary side 5 be provided, via which the two sides are mechanically coupled to each other before a mechanical impact takes place within the spring element. This means that the additional mechanical stop outside the spring element is at a smaller angle of rotation between the primary side 4 and secondary side 5 achieved as the mechanical stop within the spring element 6 would be achieved. The additional mechanical stop can be designed, for example, damped, in particular by providing an elastic element in order to minimize load shocks during mechanical striking.

Of course, it is possible in addition to the torsional vibration damper 3 in the secondary branch 9 provided second torsional vibration damper 10 in the main branch 7 position it to be in line with the torsional vibration damper in terms of power flow 3 in the secondary branch 9 is switched. In the embodiment shown, however, the second torsional vibration damper 10 in terms of power flow parallel to the first torsional vibration damper 3 arranged.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• DE 102005055795 A1 [0002]

Claims (6)

Drive train, in particular motor vehicle drive train, 1.1 with a drive machine ( 1 ) for inputting drive power to the powertrain; where 1.2 is the prime mover ( 1 ) is adapted to transmit a torque between a predetermined minimum value and a predetermined maximum value in the drive train; 1.3 with one of the prime mover ( 1 ) driven unit ( 2 ); where 1.4 is the aggregate ( 2 ) can be switched off or from a drive connection with the drive machine ( 1 ) is switchable, in the switched or in the drive connection with the drive machine ( 1 ) switched state one of the prime mover ( 1 ) exerts to be overcome first reaction torque on this and in the off or switched from the drive connection state a second reaction torque on the prime mover ( 1 ), wherein the second reaction torque is substantially smaller than the first reaction torque; 1.5 in the drive connection between the prime mover ( 1 ) and the aggregate ( 2 ) is a torsional vibration damper ( 3 ) comprising a primary page ( 4 ) and a secondary side ( 5 ), which are limited in the circumferential direction rotatable to each other and via a spring element ( 6 ), a damping fluid, a damping gas or a friction element are supported against each other; characterized in that 1.6 the torsional vibration damper ( 3 ) has a spring characteristic provided by the spring element, the liquid or the gas, which below one on the primary side ( 4 ) or secondary side ( 5 ) applied limit torque damping the relative rotation of both sides ( 4 . 5 ) causes each other and at or above the limit torque a rigid coupling in the direction of rotation between the two sides ( 4 . 5 ), and the limit torque is greater than the second reaction torque of the unit ( 2 ) and smaller than the maximum value of the torque of the prime mover ( 1 ). Drive train according to claim 1, characterized in that the limit torque less than 50 percent, in particular less than 30 percent or 20 percent of the maximum value of the torque of the prime mover ( 1 ) is. Drive train according to claim 2, characterized in that the limit torque 10 Percent to 15 percent of the maximum value of the torque of the prime mover ( 1 ) is. Drive train according to one of claims 1 to 3, characterized in that the limit torque is smaller than the first reaction torque of the unit ( 2 ). Drive train according to one of claims 1 to 4, characterized in that the drive train is designed as a motor vehicle drive train, in particular a passenger car, truck or rail vehicle, and a main branch ( 7 ), over which drive wheels ( 11 ) of the vehicle by means of the prime mover ( 1 ), in particular via an intermediate manual transmission ( 8th ), and a power split in the main branch ( 7 ), especially in the direction of the power flow in traction mode seen before the manual transmission ( 8th ), it is provided via which drive power from the main branch ( 7 ) and the aggregate ( 2 ) via a secondary branch ( 9 ), and the torsional vibration damper ( 3 ) in the power split or in the secondary branch ( 9 ) is provided. Drive train according to claim 5, characterized in that in the main branch ( 7 ), in particular in the direction of the power flow in the traction mode before the power split, a second torsional vibration damper ( 10 ) is provided, the damping of torsional vibrations in the entire torque range of the drive machine ( 1 ) to its maximum value of torque.