FR2796600A1 - Drive train for automotive vehicle includes coupling members having their coupling states established independently from coupling state of other coupling members - Google Patents

Abstract

Drive train (1) has drive unit (2), exit unit (7), and mobile mass (5) that is connected to drive unit by separation coupling member (4), and to exit unit by starting coupling member (6). Coupling states of coupling members are established independently from coupling state of other coupling members, and are maneuvered by disengaging assembly (16) with the axially movable disengagement device (15). An Independent claim is also included for the assembly method.

Description

The present invention relates to a drive train, in particular for motor vehicles called simply vehicles in the following, which consists of at least one drive unit, a movable mass and output unit arranged in such a way that the moving mass can be coupled to the drive unit by means of a separation coupling and coupled to the output unit by means of a starting <B> or </ B> switching coupling; the invention also relates to a method of implementing such a device.

Already known <B> already </ B> drive trains in which a moving mass <B> to </ B> free rotation can be isolated, two couplings, both of the drive unit, for example a combustion engine <B> than the output unit, for example a gearbox, to be used as mass of inertia. Also known are drive trains in which the rotor of an electrical machine is fixedly connected to the moving mass or constitutes it, so as to <B> to </ B> allow hybrid drives <B> to </ B> using these layouts.

These drive trains generally comprise double couplings which are equipped with two separate release systems to individually maneuver the two couplings to establish the four possible coupling states: open / open, open / close, closed / open, and closed / closed; this allows an extended use of the electric machine, for example as a start-up unit for the combustion engine, as a current generator, as a partial drive, as a total drive, as well as as a transformer unit. kinetic energy energy during slowdown process of the vehicle while the engine <B> to </ B> combustion is uncoupled, that is to say in recovery mode. For example, German patent DE-OS 44 34 <B> 019 </ B> which includes such a double coupling <B> to </ B> two separate systems can be mentioned here <B> to </ B> as an example. clearance.

A disadvantage of this dual release device is its high weight, high costs, as well as space requirements and the large number of different parts. These systems also require adaptations on the gearbox side as they mainly require radially nested clearance systems that require an additional hollow shaft or boxed input shaft to be hollow in the area. where the release system is mounted.

Several variants of solution <B> to </ B> a single clearance system have been proposed, as in the German patent DE-OS <B> 29 31 515 </ B> for example, but none offers the possibility of close the starter coupling when the separation coupling is open. This is <B> there </ B> a disadvantage in particular when a vehicle must be used economically recovering kinetic energy during slowing of the vehicle because the vehicle is then slowed by means of a energy recovery process, such as electrical power generation by means of the electric machine, when the starter coupling is closed and the combustion engine is uncoupled due to drag couples which would reduce the recovery yield.

It is therefore the main object of the present invention to provide a drive train, and a corresponding method of implementing the latter, which make it possible to recover the energy of the vehicle during the slowdown process, and to benefit from a low weight and a simple structure.

It is an additional object of the invention to provide economical manufacture and assembly of a drive train by optimizing the number of elements used.

According to a first aspect of the invention, this object is achieved by a drive train, in particular for a vehicle, which consists of at least one drive unit, a moving mass element and an output unit. wherein: the movable mass element can be coupled to the drive unit by means of a separation coupling and be coupled to the drive unit. output by means of a switching start <B> or </ B> coupling, and the at least two couplings which can each be in an open and closed coupling state are operated by means of a single release arrangement <B> to </ B> axially movable release element, characterized in that the coupling states of one coupling can be established independently of the coupling state of the other coupling.

The drive train allows the vehicle to be operated in such a way that kinetic energy is accumulated in the moving mass element when the vehicle is driven by inertia. When the separation coupling is open and the starter coupling closed, purely mechanical recovery is possible and the energy can be used to restart the vehicle, continue running or start the engine, closing the appropriate coupling.

It may be advantageous to couple an additional moving mass <B> to the movable mass element: such coupling may be caused by automatic devices: magnetic and / or centrifugal force <B> for example, or gearboxes or freewheels that introduce the additional mass into the circuit or exclude it in the direction of the torque. The contents of the German document DE 199 16 936.6, which discloses possible configurations, are all included by reference in the present application, the rotor mentioned in this document can be replaced by a moving mass or perform its role. .

It may be advantageous to provide a mechanism such as a rotary mechanism where teeth with angled teeth make it possible to introduce the additional mobile mass into the circuit. The latter may be coaxial with the drive shaft, or their axes may be parallel, and the flow of force may be transmitted by gears, belts, friction surfaces, and / or the like. At least one of the two couplings may be a friction coupling which comprises: an axially movable pressure plate under the effect of the opposing disengagement element <B> to </ B> an axial effect energy accumulator which determines the frictional contact, an axially fixed movable mass member including at least one friction contact surface, and a coupling disk which is connected in commitment <B> to </ B> rotation <B> to </ B> the drive shaft or <B> to </ B> the output shaft and that can be brought axially into frictional contact by means friction linings between friction contact surfaces of the pressure plate and the moving mass element.

Maneuvering the couplings to <B> to </ B> activate all the coupling states can be performed by means of a continuous axial displacement cycle of the displacement device.

The clearance arrangement <B> or, </ B> in other words, the clearance system can be operated manually or automatically.

The operation of the disengagement arrangement can be carried out hydraulically, pneumatically, electrically or in a combination of these ways.

The disengagement arrangement may be arranged around the output shaft.

The axially movable disengaging device may be arranged around the output shaft.

A drive unit, for example a combustion engine, can be connected indirectly or directly to the output shaft by means of one of the couplings.

A rotor of an electric machine can be attached in rotation to the outer periphery of the moving mass element.

The separation coupling can take place between the drive shaft and the moving mass element.

The switching coupling can take place between the moving mass element and the output shaft. It can be provided that the pressure plate of the switching coupling is axially movable by means of the release device in opposition to the axial effect of an energy accumulator which clamps the pressure plate. of the switching coupling on the movable mass element to form the <B> to </ B> friction, and that is how the switching coupling is operated in this way.

It can also be provided that a coupling cover connected to the pressure plate of the separation coupling is axially movable by means of the release device in opposition to the axial effect of an energy accumulator. that squeezes the pressure plate of the separation coupling on the moving mass element to establish the friction engagement, and that is how the separation coupling is maneuvered .

The switching coupling can be operated by means of the disengaging device by axially biasing radially inwardly facing energy accumulator arms, for example spring tongues <B> to disk </ b>. a spring <B> to </ B> disk.

The separation coupling can be operated by means of the disengaging device by axially biasing radially inwardly facing coupling cover arms.

The radially inwardly widened coupling cover arms may be biased by the disengagement device with the radially enlarged arms inward of the energy accumulator of the switching coupling axially interposed.

The radially inwardly widened arms of the energy accumulator of the switching coupling 'can penetrate axially <B> to </ B> through recesses provided in the radially enlarged arms towards the inside of the cover. coupling.

Starting from a state of rest of the disengagement device in the direction of its axial displacement, provision may be made for the arms oriented radially inwardly of the energy store of the switching coupling to be solicited first and foremost. the arms oriented radially towards the inside of the coupling cover are then urged. The switching coupling can be disengaged in the first place during an axial displacement of the disengagement device in the direction of the drive unit.

It can further be provided that when the switching coupling is open, the disengagement device opens the separation coupling by axial displacement of the coupling housing towards the drive unit.

it can also be provided that it is an axial displacement of the coupling housing towards the drive unit which closes the switching coupling, when the switching coupling and the separation coupling are both open.

The frictional contact between the friction lining support of the pressure plate and the frictional contact surface of the moving mass element of the switching coupling may result, when the separation coupling is open, from a force play of energy accumulators provided for biasing the pressure plates of the switching coupling and the separation coupling.

The axial effective constant of energy accumulator, for example the elastic constant of the energy accumulator <B> to </ B> axial effect of the separation coupling can be greater, taking into account the lever ratios, <B> to </ B> that of the energy accumulator of the switching coupling.

The coupling cover can be connected to the pressure plate of the separation coupling by means of axially extending threaded studs distributed over the periphery and passing through the movable mass element.

The threaded studs can be arranged radially <B> to </ B> outside the pressure plate of the switching coupling. Threaded studs can be screwed to the pressure plate and / or the coupling cover.

The two pressure plates can be arranged <B> to </ B> approximately on the same periphery.

At least one of the couplings may be equipped with tapered friction surfaces.

The separation coupling may have tapered friction surfaces such that the small radius of the frustoconical friction surfaces is oriented toward the drive unit unit.

An axially fixed support plate may be formed of at least one flange element connected to the rotor and widened radially inwards, to form at least one coupling, the support plate resting by means of an accumulator of energy <B> to </ B> axial effect on at least one component which is connected to the rotor and forms at least one bearing surface for this accumulator and the coupling disc <B> to </ B> fittings friction device being arranged axially between the pressure plate and the support plate.

The component which forms at least one bearing surface can form the bearing surfaces for the energy accumulators of the two couplings.

The component may be a flange element that widens radially inwardly and has two bearing surfaces arranged on different peripheries, the energy accumulator siappeating a radially outer surface <B> or </ B> radially inner depending on the position of the release device, and a bearing surface provided on the pressure plate being provided radially between the two bearing surfaces of the flange member. It can be provided that the energy accumulator is arranged substantially without stress when the coupling is open, and that it clamps the pressure plate against the support plate during a maneuver in each of the two axial directions.

The energy accumulator can establish two closed states of coupling according to the axial position of the disengagement device.

The coupling which has the two closed coupling states depending on the position of the disengagement device may be the starting or switching coupling.

provision can be made for the disengagement device to intervene axially on an arrangement <B> with </ B> levers for biasing the two couplings, one of which has two coupling states closed as a function of the axial position of the disengagement device, and that the lever arrangement consists of a first lever system for axially biasing the energy accumulator of a switching coupling and biasing the energy accumulator for generating a first closed coupling state of a second coupling, and a second lever system for generating the second closed coupling state of the second coupling.

The separation coupling which consists of a <B> to </ B> friction coupling can be bypassed by means of a coupling <B> to </ B> positive engagement.

The <B> positive engagement coupling can be coupled by means of the lever arrangement, in particular by means of the lever system which operates the coupling to bypass. The positive engagement coupling and the separation coupling can separate the drive unit from the moving mass element.

Positive engagement coupling <B> may be released during axial movement of the release device after opening of the starter coupling and prior to opening of the separation coupling <B> to < Friction.

The lever systems can be axially movable relative to one another.

Starting from a basic state in which the two couplings are closed, provision can be made for the first lever system to be operated firstly during an axial displacement of the disengagement device and to open the coupling <B> to < / B> two closed coupling states, and that the first lever system is moved axially on the second lever system and the second lever system is not moved axially.

The two lever systems may each comprise at least one axial stop which acts on the lever in <B> to </ B> force in the axial direction to manipulate the energy accumulators.

The two energy accumulators can be solicited by means of one of the two stops.

One of the two energy accumulators may be biased by the stopper by interposing a transmission arrangement to lengthen the disengagement path.

The transmission arrangement may consist of two radially inwardly widened flange members and connected one to the other in force engagement, the first element flange being suspended in the energy accumulator <B> to </ B> axial effect of the pressure plate that it solicits and the second flange member resting on the stop.

The axial connection of the flange members may be provided on the inner periphery thereof.

Recalling the flange elements can be effected by means of another energy accumulator <B> to </ B> axial effect.

The moving mass element can be housed <B> at </ B> rotation on the drive shaft <B> or </ B> on a component that is connected to it in a fixed manner.

The rotor can be housed <B> at </ B> rotation on the drive shaft or on a component that is fixedly connected <B> to the </ B> drive shaft.

The component can be a flange connected <B> to the drive shaft. The support plate or rotor can be housed radially <B> at </ B> the outside of screwing the flange with the drive unit.

The flange can be rotatably accommodated to rotate the drive disc to friction linings for the separation coupling.

A torsional vibration damper may be provided in the force path between the drive shaft and the output shaft.

The torsional oscillation damper can be provided in the force flow between the starter coupling and the output gear.

The torsional oscillation damper may be provided in the coupling disc <B> to friction linings.

The torsional oscillation damper may be provided in the force path between the drive shaft and the starter coupling.

The torsional oscillation damper may be a split flywheel, which consists of at least two moving masses rotating relative to each other in opposition to <B> > the effect of energy accumulators intervening in the peripheral direction.

One of the moving masses may be the moving mass element or the rotor.

The divided flywheel may comprise a primary movable mass which is fixedly connected to the driving shaft and movable to rotation relative to a secondary moving mass which <B> y </ B> is accommodated <B> to </ B> rotation, in opposition <B> to </ B> the effect of energy accumulators, the mass element mobile or the rotor of the secondary mobile mass can be introduced into the circuit by means of the separation coupling.

The moving mass element or the rotor and the secondary movable mass can be housed separately from one another on a flange permanently connected to the drive shaft.

The coupling disk of the separation coupling can be fixedly connected to a connected disk element to the secondary mobile mass.

The energy accumulators of the split flywheel can be arranged <B> to </ B> approximately <B> at </ B> a radial height equal <B> to that of the rotor.

The double coupling may be equipped for at least one coupling of a friction lining wear compensation device.

It can be provided that the wear compensation device intervenes for the two couplings.

According to a second aspect, the invention provides a method of operating a drive train, in particular for a vehicle, which consists of at least two sets connectable to a tree by means of at least two couplings with release assembly, in which coupling states of first and second couplings are operated by means of a clearance assembly <B> to </ B> axially movable release device, characterized in that the clearance assembly makes it possible to establish the following four coupling states: a) first closed coupling, second coupling, closed, <B> b) </ B> first closed coupling, second coupling open, <B> C) </ B> first open coupling, second open coupling, <B> d) </ B> first open coupling, second closed coupling In one mode, the coupling states are switched sequentially in the following order: partially closed, second coupling, closed, <B> b) </ B> first closed coupling, second open coupling, <B> C) <first open coupling, second open coupling, <B> d) </ B > first open coupling, second closed coupling It can be expected that a reciprocating <B> to and fro of the continuously moving axial disengagement device sequentially switches the coupling states into the next order: a) first closed coupling, second coupling, closed, <B> b) </ B> first closed coupling, second open coupling, C) first open coupling, second open coupling, <B> d) </ B> first open coupling, second closed coupling According to an advantageous structure, the first coupling is a separation coupling which couples together in force <B> to force the two assemblies and the second coupling is a starting coupling which couples < B> to </ B> an output shaft sets according to the coupling state of the separation coupling.

Both sets can be a combustion engine and an electric machine.

it can be expected that starting from a starting point where the two couplings are closed, the operation of the couplings is effected in a direction in opposition <B> to </ B> the axial effect of at least one accumulator.

Maneuvering the couplings can be done by pulling or pushing the release device. The objects, features, and advantages of the present invention set forth above as well as others will become more apparent from the following description of preferred embodiments in conjunction with the drawings in which: Figure <B> 1 </ B> represents a schematic arrangement of a drive train according to the invention; Fig. 2 is a partial cross-sectional view of an exemplary embodiment of a drive train; Figure <B> 3 </ B> is a partial cross-sectional view of another exemplary embodiment of a drive train; Figure 4 is a cross-sectional view of still another embodiment; Figures 5a to 5d are partial sectional views of the exemplary embodiment shown in Figure 2 for mating states that can be established; Figures 6a to 6d are partial sectional views of the exemplary embodiment shown in Figure 4 for mating states that can be established; Figures 7a and 7b show in partial cross-sectional view a coupling with dual control according to two embodiments; and Figures 8a and 8b show details of an engagement arrangement of a positive engagement coupling.

Figure <B> 1 </ B> schematically represents an exemplary embodiment of a drive train <B> 1 </ B> conforming <B> to </ B> the invention in which a drive unit 2, which can be a combustion <B> engine transmits a torque, <B> to </ B> using a drive shaft <B> 3, </ B> at first coupling 4 which acts as a separation coupling for coupling the driving unit 2 <B> to </ B> a moving element <B> 5 </ B>. The moving mass element <B> 5 </ B> can be coupled <B> to </ B> using a second coupling <B> 6 </ B> which can perform the coupling function of start <B> to </ B> the output unit <B> 7 </ B> which can be a gearbox or in other words gearbox, eg a gearbox < B> to </ B> automatic maneuver, an automatic transmission <B> to </ B> several reports, a gearbox <B> to </ B> continuous variation <B> or </ B> CVT according to the initials of the word "constant variable transmission", <B> or </ B> similar, the coupling may also be used as a switching coupling for shifting, in the case of a box <B> to < / B> several reports.

Output shaft <B> 8 </ B> or box input shaft, fixedly connected <B> to </ B> rotation <B> to </ B> mating <B> 6, </ B> passes <B> to </ B> the output unit <B> 7 </ B> the torque induced by drive unit 2; this torque is then transmitted to the driving wheels <B> 11 </ B> by the output shaft <B> 9 </ B> of box and differential <B> 10 </ B> according to the existing gear ratio in the output unit <B> 7, </ B> the drive train shown can also be a drive <B> to </ b> four-wheel drive in a manner known per se.

The movable mass element <B> 5 </ B>, which consists of a connecting element such as a flange element Sa and a moving mass Sb provided preferably radially <B> to </ B> l outside, can be isolated from the drive unit 2 and the output unit <B> 7, to </ B> using the two couplings 4, <B> 6 </ B> and can turn freely; this makes it possible to accumulate a rotational energy during an acceleration of the moving mass element B by the drive unit 2 when at least the separation coupling 4 is closed, or by the output unit <B> 7, </ B> for example during a slowing of the vehicle while the starter coupling is closed and kinetic energy is transmitted; this accumulated energy can be restored then <B> to </ B> the drive unit 2 for example for its start, and / or <B> to </ B> the output unit <B> 7 </ B> as a driving aid, it is understood that it can be very advantageous to replace the moving mass Sb of the <B> 5 </ B> moving mass element with a rotor 12 of an electric machine <B> 13, </ B> which makes it possible to achieve the flywheel use effect by other advantageous configurations, the rotor 12 being arranged radially <B> to </ B> inside the stator 14 fixed on the housing of the drive unit 2 and / or the output unit <B> 7. </ B> In many configurations, the stator 14 can be arranged radially <B> to </ B> inside of the rotor 12, the rotor 12 enveloping in this case the stator 14 <B> to </ B> by means of corresponding connection means. Examples of embodiments which include an electric machine <B> 13 </ B> may for example also generate electrical energy <B> from </ B> from the kinetic energy of the vehicle when the electric machine <B> 13 </ B> works as a generator while the start coupling <B> 6 </ B> is closed, which allows to choose an electrical and / or mechanical method to exploit the recovery energy. It is understood that it may further be advantageous to disconnect in this case the drive unit 2 <B> to drag torque, in order to increase the efficiency of the energy conversion; but it is also possible to close the separation coupling 4 to increase the slowing down and to use the drag torque to slow down the vehicle, before using the vehicle brakes or simultaneously. The electric machine also makes it possible to start <B> or </ B> by pulsing the drive unit 2 and it can also act as an auxiliary unit of the drive unit 2, or to drive the vehicle alone.

The drive unit 2 can also be started <B> at </ B> using the electric machine <B> 13, </ B> independently of the rotational energy stored in the element <B > 5 </ B> of moving mass, preferably by providing that the starter coupling <B> 6 </ B> is open; this start can be made as desired and for example depending on the outside temperature and / or the temperature of the drive unit 2 by means of either a direct start when the separation coupling 4 is closed or a pulse start by arranging the starter coupling 4 in an initially open position to accelerate the moving mass element and then closing the coupling 4, and providing that the electric machine <B> 13 < / B> is disconnected after the closing of the coupling 4, or it can still act as a drive when the separation coupling 4 is closed when the starting behavior is more difficult.

<B> A </ B> With this effect, the couplings 4, <B> 6 </ B> can be correspondingly operated by the axially movable disengaging device 15 which is a component of the disengagement arrangement <B> 16. </ B> The clearance arrangement <B> 16 </ B> can then be provided to be arranged directly axially between the drive unit 2 and the output unit <B> 7, </ B> > or preferably axially between the coupling <B> 6 </ B> and the output unit <B> 71 </ B> and / or coaxially around the output shaft <B> 8. </ B Advantageously, the release device <B> 15 </ B> can intervene directly on the coupling <B> 6 </ B> or <B> at </ B> another location, for example on the end of coupling <B> 6 </ B> opposite <B> to </ B> output shaft <B> 8. </ B> return movement of the release device <B> 15 </ B> can be transmitted to couplings 4, <B> 6 to </ B> with the aid of corresponding means, for example a push or pull rod e in the output shaft <B> 8 </ B> reamed <B> at </ B> this way effect <B> at </ B> be hollow.

The release system is controlled and powered by a management device <B> 17. </ B> In the simplest case, the management device <B> 17 </ B> may be a pressure distribution device, a similar Bowden cable, <B> or </ B>, which drives the release arrangement <B> 16 </ B> after entering an instruction signal from <B> to </ B> > Maneuver one and / or the other of the two couplings 4, <B> 6 </ B> and which correspondingly moves the release device <B> 15. </ B> It is understood that the unit of management <B> 17 </ B> and the clearance arrangement can be united into a single unit and that this unit can be mounted <B> at </ B> another location in the vehicle, so that only the device clearance <B> 15, </ B> which is for example a servo cylinder unit of a hydraulic device <B> 16 </ B> operated for example by electric motor, must be mounted in the zone of the couplings 4, <B> 6. </ B>

For the operation of the two couplings 4, <B> 6 </ B> by the coupling device <B> 15 </ B> are provided lever arrangements <B> 19, </ B> 20 which are controlled by the release device <B> 15 </ B> preferably <B> to </ B> preferably disengage the couplings 4, <B> 6. </ B> During the course of an axial stroke of release device, the two couplings 4, <B> 6 </ B> can be disengaged, and the coupling 4 can be re-engaged while the coupling <B> 6 </ B> is open. All the coupling states of the two couplings 4, <B> 6 </ B> can thus be switched <B> to </ B> by means of a travel of the release device.

Switching of the coupling states is then preferably performed according to the sequence a. <B> b, </ b> c, <B> d </ B> defined as follows: a) separation coupling 4 closed , starter coupling <B> 6 </ B> closed <B> b) </ B> separation coupling 4 closed, starter coupling <B> 6 </ B> open C) separation coupling 4 open, coupling start <B> 6 </ B> open <B> d) </ B> separation coupling 4 open, starting coupling <B> 6 </ B> closed The individual coupling states are for example used in the states following vehicle operation: coupling condition a during normal operation of the vehicle; coupling state <B> b </ B> when starting drive unit 2, in order to charge the not shown electric accumulator <B> to </ B> with the aid of drive unit 2 and / or during gearshift in a <B> to </ B> gearbox <B> 7; </ B> coupling condition c during vehicle stopping, a use operation of inertia effect of moving mass element <B> 5, </ B> acceleration of moving mass element <B> 5, </ B> or rotor 12 by electric machine <B> 16 </ B> Coupling state <B> d </ B> for recovery, preferably, when drive unit 2 is stopped.

A possible cycle of operation of a vehicle, which includes an exemplary drive train <B> 1 </ B> of the invention comprising a rotor 12 which serves as a mass <B> 5 </ B> element mobile and a gearbox <B> 7 </ B>, can be represented by the coupling states indicated in parentheses: the vehicle is stopped (c), the drive unit 2 is started <B> (b ), </ B> the vehicle is moving (a), shifting <B> (b), </ B> the vehicle is moving (a), recovering <B> (d), </ B> the vehicle moves (a), recovery <B> (d), </ B> the vehicle stops (c).

Figure 2 shows an example of <B> 101 </ B> configuration of drive train <B> 1 </ B> in Figure <B> 1, where only the layout of the area axially between the drive unit and the output unit is shown. This area consists of the two couplings 104, <B> 106 </ B> and the movable mass element <B> 105 which can be isolated from the output unit and the unit. drive and which is surrounded radially <B> to </ B> the outside by a rotor 112 of an electric machine whose stator is not shown.

The moving mass element <B> 105 </ B> has a radial extension disk element <B> 155 which is housed <B> at </ B> rotation by means of a bearing < B> 150 to </ B> rollers and which is axially fixedly connected to an axially configured shoulder <B> 153 of a flange member <B> 132 which is connected <B > to </ B> the drive shaft <B> 103 </ B> by the screws <B> 151. </ B> This housing is made radially immediately <B> to </ B> the outside screws <B> 151 </ B> but can also be made radially <B> to </ B> inside the screws <B> 151. </ B> The bearing <B> 150 </ B> is fixed axially by means of the retaining brackets 154 riveted <B> to </ B> the flange element <B> 162. </ B> On the outer periphery of the disk element <B> 155 </ B> is provided an axially extending tubular flange <B> 156 </ B> for receiving the rotor 112 which is integrally formed on the disk element or is made as a separate component which can be connected <B> to </ B> the latter for example by welding, screwing and / or riveting and which has two stops 156a, <B> 156b </ B> to axially fix the rotor 112. The end of the flange <B> 156 </ B> which is facing the drive shaft <B> 103 </ B> also has a radially inward extension <B> 157 </ B> which <B> y </ B> is mounted by means of pin <B> 157b, </ B> rivets, screws, bolts or the like, and which has a bead 157a, shaped on the entire periphery or in segments, to receive the energy accumulator <B> 158 </ B> which axially urges the pressure plate <B> 130 </ B> of the separating coupling 104.

Friction surfaces 134, <B> 135 </ B> are provided in the flange member <B> 155 </ B> for each coupling 104, <B> 106 </ B> to establish the frictional contact of the flanges. two couplings 104, <B> 106 </ B> with friction linings <B> 137 </ B> or <B> 138, </ B> and friction surfaces 130a, 13la respectively complementary are provided in the trays pressure <B> 130, 131. </ B> When the coupling <B> 106 </ B> is engaged, the pressure plate <B> 131 </ B> of the starter coupling <B> 106 </ B> is loaded with the flange element <B> 155, </ B> the friction linings <B> 138 </ B> being interposed axially to establish the friction coupling, in opposition <B> to </ B> the axial effect of an energy accumulator <B> to </ B> axial effect, for example the spring <B> to </ B> disk <B> 159, </ B> on an annular bulge or on segments <B> 131 </ B> of annular bulge distributed on the periphery is provided <B> to </ B> this effect. The spring <B> to </ B> disk <B> 159 </ B> is supported axially on an energy accumulator <B> to </ B> axial effect, for example a spring <B> 160 </ B> sensor, which itself relies in opposition <B> to </ B> the effect of the spring <B> to </ B> disk <B> 159 </ B> by means of a profile outside 160a on corresponding recesses 16la in the inner peripheral area of the coupling cover <B> 161, shaped axially in the direction of the drive shaft <B> 103. </ B> The tabs < B> 162 </ B> spring <B> to </ B> disc spring <B> to </ B> disc <B> 159 </ B> extended radially inward are biased axially by the stopper clearance <B> 103 </ B> of the release device not shown in more detail, and constitute a lever <B> to </ B> two arms <B> to </ B> point of rotation at contact 164 with the <B> 160 </ B> sensor spring. The pressure plate <B> 131 </ B> is axially movable and is attached in rotationally engaging <B> engagement to the coupling cover <B> 161 by means of the springs. <B> to </ B> blade <B> 135 </ B> which are oriented in the peripheral direction and are arranged in such a way that one end of each of the <B> blade <B> springs <B> > 165 </ B> is attached to the pressure plate <B> 131 </ B> by means of rivets <B> 166 </ B> distributed on the periphery and that the other end of each spring is attached to the lid coupling <B> to </ B> using rivets that are not shown. It is understood that it may also be advantageous to use other fastening means such as screws, rivet buttons provided at least in the coupling cover which can be crushed after the coupling. insert springs <B> to </ B> blade <B> 165. </ B>

The <B> 138 </ B> coupling disc <B> 133 </ B> friction liners are connected, for example, riveted, <B> to </ B> using the 140 gaskets friction. In the example shown, the coupling disk <B> 133 </ B> is equipped with a two-stage torsional oscillation damper 133a, which includes a damper stage <B> 133 </ B> main and a stage 133c prior damping and any associated friction arrangements. Such shock absorbers torsion oscillations are known per se. A torsional oscillation damper which is substantially identical to that of the present embodiment is described in more detail in the DE 198 application which is thus fully incorporated. in this application. It is understood that it may also be advantageous to use coupling discs of another configuration, for example without damper, or comprising only one or more damping stages. The hub <B> 133d </ B> of the coupling disk <B> 133 </ B> is fixedly connected in rotation <B> to the </ B> output shaft, for example <B> to </ B> the gearbox <B> 108 </ B> input shaft that follows downstream into the force train and is not shown in more detail.

The coupling cover <B> 161 </ B> is provided axially movable for the control of the coupling 104. The bolts <B> 167 </ B> which are distributed on the outer periphery of this cover, which are rotated in the axial direction towards the pressure plate <B> 130 </ B> and are fixed in the zone of the outer periphery of this lid by fixing means such as screws <B> 167b, </ B> rivets <B > or </ B>, enter the <B> 155 </ B> flange <B> to </ B> through corresponding openings <B> 108 </ B> and are connected in a fixed manner rotation and axially fixed to the pressure plate <B> 130, </ B> for example by means of an external thread 167a provided on the bolt <B> 167. </ B>

Coupling <B> 106 </ B> is released by axial biasing of spring <B> 162 </ B> tabs <B> to disk by release stop <B> 163, </ B > so that the spring <B> to </ B> disk <B> 159 </ B> is biased axially against the coupling cover <B> 161 which is supported on the flange element <B> 155 </ B> through pressure plate <B> 133 </ B> and friction linings <B> 137. </ B>

When the coupling <B> 106 </ B> is disengaged, the coupling 104 is disengaged when the tongues <B> 162 </ B> of the spring <B> to </ B> are pushed axially, after a displacement of the stop <B> 163 </ B> clearance, against a collar <B> 169 </ B> provided on the inner periphery of the coupling <B> 161 </ B> and that the stop <B> 163 </ B> Release was moved further in the same direction. By using the necessary return force <B> to </ B> this effect, the coupling cover <B> 161 is then axially displaced in opposition <B> to the elastic spring constant <B> to </ B> drive <B> 158 </ B> by driving the pressure plate <B> 131. </ B> This removes the tightening and therefore the <B> commitment to </ B> friction between the pressure plate <B> 130 </ B> and the flange element <B> 155 </ B> and the friction linings <B> 137 </ B> interposed between them. This results in a state in which the two couplings 104, <B> 106 </ B> are open. In this state, no torque is transmitted from the drive unit <B> to </ B> the flange element <B> 155 </ B> and vice versa by the friction linings <B> 137 < / B> to friction linings <B> 139 </ B> which are fixedly connected in rotation and axially movable <B> to </ B> the flange element <B> 132 </ B> of the drive shaft <B> 103 </ B> by means of springs <B> to </ B> blade <B> 170 </ B> whose arrangement is similar <B> to </ B> that of the springs <B> to </ B> Blade <B> 165. </ B>

If the axial displacement of the clearance stop is continued, the distance between the axially fixed flange element <B> 155 </ B> and the pressure plate <B> 131 </ B> is reduced again and the contact Friction of the coupling <B> 106 </ B> is restored, while the coupling 104 remains open. The frictional contact is then determined by the two elastic constants of the two springs <B> to </ B> disks <B> 158, 159 </ B> and can be made in a manner <B> to </ B> ability to transmit the maximum torque of the electrical machine by its rotor 12 <B> to </ B> the output shaft <B> 108 </ B> or a corresponding torque of the drive shaft <B> 108 < / B> by the pads <B> 138 </ B> to the rotor 112 in the case of a recovery.

In this exemplary embodiment, the coupling 104 is provided as a tapered coupling 104 for optimizing the transmittable torque which also includes the torque spikes of the drive unit caused by the torsional oscillations. The friction surfaces 130a, 134 are therefore inclined with respect to the rotational direction plane, and the <B> 139 </ B> supports of the friction linings are correspondingly adapted and can be displaced axially by means of springs <B > to <B> 170 </ B> to establish frictional contact by friction linings <B> 137 </ B> to avoid double centering of the flange element <B> 132 </ B> on the input shaft <B> 103. </ B> It is understood that the coupling 104 can also be realized as a conventional coupling or coupling <B> to </ B> several discs, and / or that torsional oscillations can be reduced or eliminated by means of corresponding dampers of torsional oscillations introduced into the force flow between the drive unit and the separation coupling 104.

The arrangement shown in particular comprises a wear compensation adjustment generally called simply wear compensation in the following, in particular for the wear of friction linings <B> 137, 138. </ B> It It is particularly advantageous here that a single wear compensation arrangement <B> 180 </ B> occurs on the friction linings <B> 137, 138 </ B> of the two couplings 104, <B> 106. </ The arrangement <B> 180 </ B> is used in the present embodiment as a function of a sensor spring, for example a sensor spring <B> 110 </ B>. In other exemplary embodiments, it may be advantageous to use a wear compensating arrangement that operates in accordance with a path sensor that detects wear of the friction liners. In the case of the <B> 110 </ B> sensor spring of the example shown, an axial excursion towards the drive shaft <B> 103 </ B> occurs in case of wear due to an increased return force on the <B> 162 </ B> tabs of the spring <B> to </ B> disk for an obtuse angle on the spring <B> to </ B> disk <B> 159 < / B> mounted on pins <B> 131b. </ B> When coupling <B> 106 </ B> is closed, the sensor spring allows a certain clearance <B> to </ B> a ring < B> 181 </ B> in ramp which supports the spring <B> to </ B> disk <B> 159 </ B> on the point of rotation 164 in axial opposition to the spring <B> 160 </ B> of sensor. Therefore, this ring compensates the clearance by a peripheral rotation in which ramps 18la axially shaped and distributed over the periphery reestablish contact with the spring <B> to </ B> disc. The ring <B> 181 </ B> is supported in its peripheral rotation by accumulators of force <B> 182 to </ B> effect in the peripheral direction which intervene on the one hand on arms <B> 181b < / B> oriented radially of the ring <B> 181 </ B> and which on the other hand rely on solicitation <B> 161b </ B> of the cover <B> 161 </ B> coupling. The energy accumulators <B> 182 </ B> may be mounted in window-shaped openings in the coupling cover <B> 161 and constitute in the peripheral direction a limitation of the window-shaped openings the solicitation arrangement <B> 161b. </ B>

Figure <B> 3 </ B> represents a fraction of the exemplary embodiment in which the two couplings 204, <B> 206 </ B> and the moving element <B> 205 </ B> as well as that the rotor 212 are arranged in principle as shown <B> in </ B> Figure 2 and described <B> at </ B> the moment, providing a damper <B> 290 </ B> d torsional oscillations in the force flow between the drive shaft <B> 203 </ B> and the separation coupling 204 to reduce the torsional oscillations of the drive unit. In the exemplary embodiment shown, no torsion damping damper is therefore provided in the coupling disk <B> 233, </ B> which is therefore simpler and which simply consists of a hub 233c , which establishes the <B> to </ B> rotation with the input shaft <B> 208 </ B> of the box, and a flange member 233a that is fixedly attached <B > to </ B> this hub and has openings <B> 233b </ B> to allow the passage of mounting tools for mounting screws <B> 251 </ B> of the whole arrangement 201 on the drive shaft <B> 203 </ B> and for friction bearing supports 240, <B> to </ B> friction linings <B> 238, </ B> arranged radially fixed <B > to </ B> the outside. It is understood that a torsion damping damper can be provided additionally in the coupling disk <B> 233 </ B> in particular cases of applications.

The torsional vibration damper <B> 290 </ B> is received axially between the drive shaft <B> 203 </ B> and the spring 212 and consists of a split flywheel including an element <B> 291 </ B> disk mounted on the drive shaft <B> 203, </ B> as the first mass on the primary side, and a second disk element <B> 292 </ B> as the second mass on the side secondary. The disk elements <B> 291, 292 </ B> are housed one on the other and an additional moving mass 292a can be connected to the latter, at least in engagement <B> to </ B> rotation. The two elements <B> 291, 292 </ B> of disks can rotate relative to <B> to </ B> the other in opposition <B> to </ B> the effect of accumulators of energy <B> 293, </ B> expected at least in the peripheral direction. it is understood that the second mobile mass can also be constituted by the element <B> 205 </ B> movable mass, so that the element <B> 292 </ B> disc and / or the moving mass 292a can be omitted. The moveable mass element <B> 205 <can then be coupled via the separation coupling 204 <B> to the disk element <B> 292 </ B> . The flange element <B> 232 </ B> establishes a frictional contact with the <B> 239 </ B> friction lining and friction linings <B> 237 </ B>. element <B> 205 </ B> moving mass and can rotate <B> to the <B> 292 </ B> disc element in opposition <B> to </ B> the effect of energy accumulators <B> 293. </ B> The separation coupling 204 can be made in a <B> way to </ B> slip during strong torque shocks and <B> to </ B> perform the function of a coupling <B> to </ B> skating.

In the exemplary embodiment shown 201, the disk element 29B is received axially on the drive shaft 203 between it and a bearing flange 294. by means of the screws <B> 251. </ B> The disk element <B> 291 </ B> has in the region of its inner periphery an axially-shaped recess 29a1 for centering the bearing flange 294. The disk element 29B is further shaped radially outwardly by means of another annular flange 291c connected thereto, for example welded, to form an annular bead <B> 291b </ B> which receives the energy accumulators <B> 293, </ B> which may be short cylindrical compression springs or arc springs preloaded advantageously to almost the diameter of use which extend over a large part of the periphery, for example <B> to </ B> about half of the periphery and can be nested one inside the other. In this annular bead can be provided, by means of thinning <B> 291d, </ B> 29le, chambers <B> 295 </ B> distributed on the periphery which receive energy accumulators <B> 293 </ B> and corresponding in number to the number of energy accumulators <B> 293 </ B> distributed on the periphery and which can be filled at least partially with lubricant and radially outwardly presenting a wear-protection shell arranged radially between the chamber wall and the energy accumulators. Thinning <B> 291d, </ B> 29le further serve as a solicitation arrangement each for one side of the energy accumulators <B> 293. </ B>

The other side of the energy accumulators <B> 293 </ B> is driven by the secondary disk <B> 292 </ B> element by means of radial arms <B> 297 </ B> which penetrate radially from inside in room <B> 295 </ B> which is here open. Continuing radially inwards, the disk element 292 has openings distributed over the periphery into which lugs 292c of the moving mass 292a, which are axially shaped, penetrate axially. corresponding way which establishes a connection in <B> to </ B> rotation between the disk element <B> 292 </ B> and the moving mass 292a. Apertures <B> 292d </ B> in the moving mass 292a are distributed over the periphery radially <B> to </ B> within the lugs 292c and spatially form for the separation coupling 204 the openings of venting on the openings <B> 292b. </ B> It may also be appropriate to arrange the openings <B> 292d, </ B> radially <B> to </ B> the outside, for example <B> to </ B> approximately <B> at </ B> the same radial height as the friction linings <B> 237 </ B> of the coupling 204 and then arranging the lugs 292c radially <B> to </ B> inside. Other configurations of connections between the mobile mass 292a and the disk element 292, together with a corresponding configuration of the openings 292b, 292d, can also be advantageous.

Friction coupling <B> 298 </ B> is provided radially <B> to </ B> between the disk element <B> 292 </ B> and the bearing flange 294. To receive the friction disk <B> 292f fixedly <B> to </ B>, the <B> 292 </ B> disk element has <B> to </ B> this effect an inner profile 292e, for example an internal toothing, which is clamped axially, between the disk element and an annular flange 292b which widens towards the outside and fixedly connected <B> to </ B> rotation with the bearing flange 294, by providing an interposed spring 298a and a friction drive disc <B> 298b </ B> which preferably penetrates, with a rotation clearance in the teeth 294a of the bearing flange 294.

The secondary element constituted by the disk element 292 and the moving mass 292a is housed on the bearing flange 294 by means of a bearing 299 to 298 rollers, being understood that a sliding bearing can also be provided to this effect. The flange element <B> 255 </ B> of the movable mass element <B> 205 </ B> is also housed by means of the slide bearing <B> 250 </ B> on the same bearing flange being axially offset. The two elements 292a, <B> 255 </ B> are then housed <B> at </ B> with different diameters on the same disk element <B> 291 </ B> <B> to </ B> the inside of the landing flange receiving <B> to </ B> different diameters. In the absence of the mobile mass 292a, it may be advantageous to omit a bearing, the element <B> 205 </ B> movable mass which acts as a secondary element being housed on the flange 294 bearing.

The <B> 232 </ B> element which receives the friction linings <B> 237 </ B> is fixedly received <B> to </ B> rotation on the moving mass 292a by means of the screws 250a and <B> y </ B> is centered.

The disk element <B> 291 </ B> can be configured, in terms of its material thickness and shape, to have axial flexibility to reduce or isolate axial oscillations or the oscillation oscillations of the drive shaft <B> 203. </ B> For example, the openings <B> 291f </ B> intended for ventilation in particular of the coupling 204 can be configured from in such a way that the axial flexibility required is preferably determined by the remaining rods between the openings <B> 291f. </ B> In order to avoid a propagation of oscillations in the secondary element, for example in the elements <B> 292 < In the case of a disk disk, the two disk elements 291, 292 have a corresponding axial clearance which is determined by an axial energy accumulator, for example the spring. <B> 296 to </ B> membrane that is attached to the disk <B> 291 </ B> element by means of tabs 296a distributed over the periphery and which can also be provided to perform a sealing function for the chamber <B> 295. </ B> By its compression, the energy accumulator <B> 296 </ B> can exert a torque of friction, for example in the radial direction, which makes it possible to propose a damping arrangement <B> to </ B> friction arrangement against axial oscillations and / or nutation of the drive shaft <B> 203. </ B>

Figure 4 shows another embodiment of a coupling unit 301, arranged for example in the coupling bell 307a of a gearbox not shown in greater detail. the coupling unit <B> 301 </ B> consists of the separating coupling 304, the starting coupling <B> 306 </ B> and the element <B> 305 </ B > mobile mass accompanied by the rotor <B> 312 </ B> of an electric machine that is not shown in more detail.

The <B> 305 </ B> moving mass element is movable <B> to </ B> rotation by means of the flange element <B> 305 </ B> on the drive shaft <B > 303 </ B> or, as shown here, is housed by means of a bearing <B> 350 to </ B> rollers on a flange 394 attached <B> to </ B> the drive shaft < B> 303 to </ B> using screws <B> 351 </ B> and preferably centered on this shaft. The <B> 350 </ B> bearing is fixed axially on a bearing flange 394 by means of a disc 394a which is preferably screwed with this flange onto the axis of rotation. Going out <B> to </ B> from this arrangement, apertures 355a are provided in the flange element <B> 355 </ B> to pass through the screw mounting tools <B> 351. </ B> The flange element <B> 355 </ B> wraps radially <B> to </ B> the outside screws <B> 351 </ B> and constitutes a body <B> 385 Axial Plot with Coupling <B> 386 to </ B> Positive Engagement Connecting in Positive and Separately Engaged Engagement Flange 394 and Flange Element <B> 355 </ B> . Operation and other details are evident in Figures 8a and 8b. </ B>

Figure 8a shows, in longitudinal view, the coupling <B> 386 to </ B> positive engagement which includes the housing flange 394 <B> to </ B> external profile <B> 394b. </ B> of an axial displacement of sliding keys 386c distributed on the periphery, an inner profile 386a complementary to the outer profile <B> 394b </ B> and formed of pawls <B> 386b </ B> movable radially and distributed on the periphery penetrates radially in positive engagement <B> to </ B> inside the outer profile <B> 394b </ B> under the effect of sliding movement along the ramp <B> 386d </ B> consisting of by the two elements 386c, <B> 386b. </ B> The pawls then penetrate <B> to </ B> through corresponding openings in the axially structured member <B> 385 </ B> flange element <B> 355 </ B>. When the sliding keys 386c have been recalled, a radially outwardly and / or centrifugally acting energy accumulator may cause a retraction of the pawls <B> 386b </ B > to open the coupling <B> 386 to </ B> positive engagement.

Figure <B> 8b </ B> represents, in cross-section, in the in-engagement state, fractions 386e of the <B> 386 mating at positive engagement represented <B> at </ B>. In Figure 8a. <B> A </ B> this Figure, the sliding key 386c pushes the inner profile 386a of the pawl <B> 386b </ B> into the outer profile <B> 394b </ B> of the flange 394b. housing, the pawl <B> 386b </ B> being moved radially <B> to </ B> through an opening in the body <B> 385 </ B> of axial structure. Such fractions 386e may constitute the positive engagement coupling by being distributed over the periphery, with an advantageous number of fractions 386e ranging from <B> 1 </ B> to 12, preferably <B> 3 </ B>. and <B> 8. </ B>

Continuing toward the outside of the flange element <B> 355 </ B>, a substantially radially oriented <B> 387 </ B> element provided with an axial <B> 388 </ B> conformation in the its outer periphery connects, as shown <B> to </ B> in Figure 4, <B> to </ B> the flange element <B> 355 to </ B> the <B> 385 </ B> oriented axially. A <B> 389 </ B> receiver for rotor <B> 312 </ B> is mounted, for example, screwed, riveted or the like, by means of a radially traced flange member 389e on the front side of the rotor. Axial conformation <B> 388. </ B> Receiver <B> 389 </ B> radially surrounds rotor <B> 312, </ B> is an axial stop 389a for rotor <B> 312 </ B > and is connected with the rotor <B> 312 </ B> in common with a support plate for <B> to </ B> the coupling 304 and in the form of an annular flange <B> 390. </ B> It may be advantageous to screw by means of through screws 312a distributed on the periphery, the bearing plate <B> 391 </ B> coupling <B> 306 </ B> which constitutes the abutment <B> 392 </ B> for the rotor <B> 312 </ B> on the opposite side with the rotor receiver <B> 389 </ B> and the support plate <B> 390. </ B> This plate <B> 390 </ B> may have <B> to </ B> this effect a thread for screwing and may also, appropriately, be guiding screws <B> 312 to </ B> left r from the support plate <B> 390 </ B> to the support plate <B> 391 </ B> which has a thread.

An annular bulge or ring bulge <B> 389b <B> segments <B> to </ B> <B> 358 </ B> spring support are provided radially <B> to </ B> the outside on the side facing the coupling 304, in the radially inwardly flanged element 389a of the rotor <B> 389 </ B> receiver. This bulge or its segments force against the <B> 390 </ B> bearing plate provided with the <B> 397 </ B> friction liners interposed, the support plate <B> 330 </ B> by means of pins 330a distributed on the periphery located further inward by forming a lever <B> to </ B> an arm. It is thus a pulled coupling 304 which is moved away from the coupling 304 by an axial displacement of the release device <B> 315 </ B> by means of the lever arrangement <B> 319. </ B> The process of clearing the coupling 304 and coupling <B> 386 to </ B> positive engagement is adapted so that the separation coupling 304 causes a release or setting process <B> to </ B> Slip and then close or engage the coupling <B> 386 to </ B> positive engagement so that the separation coupling 304 should not be exposed to the maximum torque of the drive unit.

On the side of the flange element 389e facing the starter coupling <B> 306 </ B> are provided two annular bulges, annular bulge segments or pawls 389c, <B> 389d </ B> distributed over the periphery <B> to </ B> of different diameters, the pawls 33la of the pressure plate <B> 331 </ B> distributed on the periphery being arranged radially between the pawls 389c and <B> 389d. </ B>

Figures 7a, <B> 7b </ B> show two possible embodiments of a coupling <B> 306 </ B> operated in this way, the example shown <B> to </ B> Figure 7a being used <B> to </ B> Figure 4. The spring <B> to </ B> disk <B> 359 </ B> can be tightened, depending on the position of the release device <B> 315 </ B> (Figure 4) between the segments 389c, <B> 389d </ B> on the one hand and ratchets 33la on the other hand. When spring <B> to </ B> disk <B> 359 </ B> rests on radially inner pawls <B> 389d </ B> by forming a lever <B> to </ B> two arms , the closed coupling <B> 306 </ B> opens when the release device <B> 315 </ B> moves towards the coupling <B> 306. < / B> Coupling <B> 306 </ B> closes when this device is moved axially away from coupling <B> 306, </ B> when spring <B> to < / B> disk <B> 359 </ B> relies on the <B> 389d </ B> radially outer pins, forming a lever <B> to </ B> an arm. It is understood that the pressure plate <B> 311 </ B> as the pressure plate <B> 330 </ B> is axially movable and is fixedly connected <B> to </ B> rotation to the plate of support <B> 390 </ B> or <B> 391 to </ B> using means not shown, for example the springs <B> to </ B> blade that connect the pressure plate <B> 330 </ B> or <B> 331 </ B> and the support platforms <B> 390 </ B> or <B> 391. </ B>

Figure <B> 7b </ B> represents an exemplary embodiment of a coupling <B> 3061 to </ B> the open state in which the pressure plate <B> 331 '</ B> is tightened on the support plate <B> 391 '</ B> by means of the <B> spring <B> 359' <B> 388 '</ B> being interspersed. The pressure plate <B> 331 '</ B> is moved axially in opposition <B> to </ B> the effect of the spring <B> to </ B> disk <B> 359' </ B> for releasing the coupling <B> 3061 under </ B> the effect of an axial displacement of the preferably rigid lever 359a which is supported in one direction on the lugs 389c 'and in the other direction on the lugs <B > 389d; </ B> the lever rests on the <B> 331 '</ B> pins distributed on the periphery in the direction of the displacement of the pressure plate in opposition <B> to </ B> the effect of the spring <B> to <B> 359b. </ B>

Torque transmission on the <B> 305 </ B> mobile mass element and <B> to </ B> from it is performed between the drive shaft <B> 305 </ B > and this moving mass element by means of the <B> 339 </ B> support of friction linings which receives radially <B> to </ B> outside the friction linings <B> 337 </ B> and which is fixedly connected in rotation, for example riveted, <B> to the bearing flange 394. The material thickness of the friction liner support allows axial adaptation of the friction linings to the <B> 390 </ B> backing plate or to the <B> 330 pressure plate. </ B> coupling <B> 333 </ B> which is only indicated here approximately, and which is fixedly received <B> at </ B> rotation and <B> at </ B> axial sliding by means of the hub <B> 333d </ B> is provided between the <B> 305 </ B> moving mass element and the output shaft. When the coupling <B> 306 </ B> is closed, the torque transmission is effected by means of the radially arranged <B> 338 </ B> friction linings which induce the torque in the hub <B> 333d < / B> via the support 340 of friction linings and a hub flange 333e that connects to it. A damping device <B> 333b </ B> which includes, for example, in a manner known per se, a main damper and possibly a pre-damper and / or a friction device can be active in the force train between the support 340 of friction linings and the hub <B> 333d. </ B> It <B> y </ B> should refer to Figures 2 and <B> 3 </ B> for the description of other possibilities in this exemplary embodiment, the arrangement of a split flywheel being possible in this embodiment by providing for example that the area of the support plate <B> 390 </ B> is provided with biasing means which intervene on one end of the energy accumulators intervening in the peripheral direction while the other end of each of them is fixedly connected in rotation and is biased <B> to </ B> using corresponding configuration solicitation means by a disk element which is fixedly connected <B> to </ B> rotation <B> to </ B> the drive shaft <B> 303 </ B> or <B> to </ B> a component that it is connected and which is, for example, the flange 303a which consists in the example shown in a pulse transmitter for driving the drive unit, for example a ring of ignition markings <B> to </ B > markings applied radially on the outside and which should be adapted as regards the material thickness.

The <B> 361 </ B> lever arrangement that serves to <B> to maneuver the two couplings 304, <B> 306 </ B> is moved by the release device <B> 315 to <B> / B> 315a non-turning release lever which is housed by means of a bearing <B> 315b to </ B> rollers on a receiver 315c which rotates with the output shaft <B> 308. </ B> Release lever 315a can be biased by a force in both directions and is thus actively movable axially in both directions by means of an actuator, not shown, for example an electric motor, or a hydraulic unit.

The disengagement movements are transmitted by the release lever 315a through the receiver 315c <B> to </ B> axially oriented bolts <B> 367 </ B>, distributed on the periphery and axially and axially connected. fixed in rotation <B> to </ B> this receiver. These bolts penetrate into openings <B> 333f </ B> formed correspondingly in the hub <B> 333d. </ B> According to other exemplary embodiments, it may be advantageous to configure the actuation, by a release lever <B> or </ B> a release bearing, an actuating arrangement such as spring tabs <B> to </ B> disks of a coupling such as couplings 304, <B> 306 < In such a way that a pressure ring has a bearing surface for the release bearing and also comprises pressure pins which are distributed on the circumference and oriented axially in the direction of the operating lever or tabs from spring <B> to </ B> disc and are guided axially in the toothing between the hub <B> 333d </ B> and the output shaft <B> 308. </ B> It can then be advantageous to machining in the output shaft <B> 308 </ B> of the corresponding axial guides for the pressure rods, for example by milling, and / or guide r the pressure pins in the teeth of the toothing 308a and correspondingly hollow the teeth of the hub <B> 333d to </ B> this location. To move the spring <B> to the disc that clamps the pressure plate of the coupling, the pressure pins can then intervene axially on the operating lever <B> or </ B> on the spring tabs compression, either directly or suitably <B> at </ B> their free end by means of a receiver mounted <B> to </ B> rotation <B> to </ B> using a bearing <B> to </ B> rolls. It is understood that the proposed solution may be advantageous for operating any double coupling in which a coupling disc <B> 333 </ B> is arranged between the release device <B> 315 </ B> and the operating lever < B> 335 </ B> or compression spring tabs <B> to disk <B> 359. </ B>

In the exemplary embodiment <B> 301 </ B> shown in greater detail <B> to </ B> in Figure 4, the bolts <B> 367 </ B> are connected in a fixed manner, <B> at their opposite end to the release lever 315a, to an annular receiver 364 on which the operating lever <B> 365 </ B> of the spring <B> to </ B> screw <B> 359 </ B> is received axially fixed and <B> to </ B> rotation relative to the receiver 364, by means of the bearing 364a <B> to </ B> rollers. When moving the release device <B> 315 </ B> towards the drive shaft <B> 303, </ B> the operating lever <B> 365 </ B> axially forces the spring <B> to </ B> disc <B> 359 </ B> by means of tabs 365a bent axially <B> at </ B> right angle and spread over the periphery and thereby closes the coupling <B > 306 </ B> since the spring <B> to </ B> disc leans on the pins <B> 331 </ B> as a point of rotation and squeezes the pressure plate <B> 331 </ B> on pins <B> 389d </ B> with friction linings <B> 338 </ B> and bearing plate <B> 391. </ B> The position then chosen for the release device is the extreme position of the axial displacement of the release device <B> 315 </ B> in the direction of the drive shaft <B> 303. </ B> Other axially movable <B> 366 </ B> bolts, distributed on the periphery and respectively having abutments 366a, <B> 366b </ B> provided <B> at </ B> their ends pass through the operating lever <B> 365 </ B> immediately radially <B> to </ B> inside tabs 365a bent <B> to </ B> right angle. When the release device is moved axially away from the drive shaft <B> 303, </ B> the spring <B> is tightened to disk <B> 359 </ B > by the tabs 365a is removed, and the start coupling <B> 306 </ B> is released again, and the operating lever <B> 365 </ B> comes on the abutment <B> 366b </ B> and drives the bolts <B> 366b </ B> so that the tabs 368a of the operating lever <B> 368 </ B> resting on the stop 366a are driven to open the separation coupling 304 and the coupling <B> 386 </ B> <B> to </ B> positive engagement and that an axial displacement of the operating lever <B> 319 </ B> axially connected in a fixed manner by the stop 319a to the lever of Maneuver <B> 368 </ B> is implemented in opposition <B> to </ B> the axial effect of the spring <B> to </ B> disk <B> 319b </ B> which is clamped between the spring <B> to <B> 358 </ B> coupling disc and the <B> 319 operating lever. </ B> This axial movement of the lever man <B> 319 </ B> which acts as sliding wedge <B> 386b </ B> (Figure 8a) opens coupling <B> 386 to </ B> positive engagement, and the compression spring <B> 358b </ B> is lifted from the lugs 330a of the pressure plate <B> 330 </ B> by the operating lever <B> 319, <B> spring to the <B> disk <B> 319b </ B> being interposed axially, which opens the coupling 304. When continuing the axial displacement of the release device <B> 315 </ B> which moves it away from the drive shaft <B > 303, <B> to </ B> disk <B> 359 </ B> of coupling <B> 306 </ B> comes on stop 366a and squeezes the pressure plate < B> 331 </ B> with friction linings <B> 338 </ B> since it leans on lugs 389c forming a lever <B> to </ B> an arm and intervenes on lugs 33a of the pressure plate <B> 331, </ B> which engages the coupling <B> 306. </ B>

FIGS. 5a to 5c show, in order to describe the process of the invention, the coupling states a, b, b, c, b, d. of the <B> 101 </ B> coupling arrangement that can be established. The four coupling states a, <B> b, </ B> C, <B> d </ B> can be switched by means of the release device <B> 115 </ B> in a single stroke in the direction of the shaft <B> 103, </ B> and also inversely by a displacement in the opposite direction of the release lever <B> 315, </ B> That is to say that a cycle of a constant movement back and forth of the disengagement device <B> 115 </ B> can switch states a, <B> b, </ B> <d> </ b>, <b>, </ B> has some mating.

In state a of the coupling of Figure 5a, the two couplings 104, <B> 106 </ B> are closed and the release device is in its furthest position relative to <B> at </ B> the drive shaft <B> 103. </ B> In this state a, the vehicle <B> to </ B> drive train is driven forward or backward using the arrangement <B> 101, </ B> or is stopped, a speed that can be engaged as a garage lock in a box mounted downstream. The electric machine <B> to </ B> rotor 112 can be implemented in the state a or be released, the active state of the electric machine can induce an additional torque to assist the drive unit <B > or </ B> that can receive a torque from the drive unit when it operates as a generator.

The second <B> b </ B> state of coupling is shown <B> at <B> 5b. </ B> The disengagement device <B> 115 </ B> of the Coupling arrangement <B> 101 </ B> is moved axially enough so that the tongues <B> 162 </ B> of the spring <B> to </ B> are urged and the coupling <B> 106 </ B> be cleared. In this way, the movable mass element <B> 5 </ B> accompanied by the rotor 112 is uncoupled from the output shaft <B> 108. </ B> In this state <B> b </ B> In the coupling, a gear shift can be performed in a downstream gearbox, or the drive unit can be started in direct start. It is also possible to charge the accumulators of electrical energy by driving the electric machine by the drive unit.

Figure 5c shows the coupling state c of the coupling arrangement <B> 101, </ B> wherein the two couplings 104, <B> 106 </ B> are open. State c is reached by further axial movement of the release device <B> 115 </ B> towards the drive shaft <B> to </ B> from the <B> b state . </ B> The release device <B> 115 </ B> axially compresses the <B> 162 </ B> tabs of the <B> to </ B> disk spring against an abutment ring <B> 169 < / B> coupling cover <B> 161 </ B> and moves them axially; the pressure plate <B> 130 </ B> which is fixedly connected to the coupling cover and moves too, opens the coupling 104. In this state c, the element <B> 105 </ B > continuous moving mass <B> to </ B> turn with negligible friction under the effect of the rotational pulse that exists before the opening of the coupling 104. The rotational energy thus stored can be used < B> to </ B> generate electrical energy or for a pulse start of the drive unit, the coupling 104 being closed again. This rotational energy can also be used in appropriate situations to restart or continue to move the vehicle, by closing the coupling again. <B> 106. </ B> Pulse and assistance with moving by the moving mass element <B> 105 </ B> can also be facilitated by driving the electric machine. When the movable mass element <B> 105 is stopped, it is also possible to accelerate it first by means of the electric machine <B> to </ B> rotor 112.

The coupling condition <B> d </ B> of the coupling arrangement <B> 101, </ B> in which the coupling 104 is open and the coupling <B> 106 </ B> is closed, is achieved by continuing the axial displacement of the release device <B> 116 </ B> and thus the cover <B> 161 </ B> coupling towards the drive shaft <B> 103 </ B> The pressure plate <B> 131 </ B> is then pushed against the moving mass element <B> 105 </ B> and the coupling <B> 106 </ B> is closed. The drive unit is uncoupled from the rest of the drive train, so that the vehicle can be driven exclusively electrically in this state <B> d </ B> by means of the electric machine <B> to </ B > rotor 112, <B> or </ B> that the electric machine acts as a current generator and transforms into electric energy energy transmitted on the output shaft by the drive wheels, through the box or directly, which slows down the vehicle. A recall to the other modes of operation c, <b> b, </ b> a is directly possible by moving axially the release device in the opposite direction.

Figures 6a <B> to 6d </ B> show a coupling process for <B> to </ B> switch coupling states a, <b> b, </ b> c, <b> d </ B> of the exemplary embodiment of a coupling arrangement <B> 301 </ B> of the drive train of the invention. The disengagement device <B> 315 </ B> then co-operates with the disengagement arrangement which is not shown in more detail, in such a way that the disengagement device <B> 315 </ B> can being urged by a force during an axial displacement in the direction of traction or thrust, being for example connected <B> to </ B> an electric motor included in a release arrangement, and able to work in both directions. The coupling states a <B> to d </ B> of Figures 6a <B> to 6d </ B> correspond to states a <B> to d </ B> of Figures 5a <B> to 5d </ B> regarding their use in the vehicle.

In the coupling state of Figure 6a, the clearance device <B> 315 </ B> is in its position closest to the drive shaft <B> 303 </ B> and closes. Coupling <B> 306. </ B> Coupling 304 and coupling <B> 386 to positive engagement are also closed.

In the <B> b </ B> state of Figure <B> 6b, </ B> the <B> 315 </ B> breakout device is far from drive shaft <B> 303 < / B> after an axial displacement to reach a state almost free of axial forces, in which the start coupling <B> 306 </ B> is open and the separation coupling 304 is closed with the coupling <B > 386 to </ b> positive engagement.

In state c of Figure 6c, further axial displacement of the release device <B> 315 </ B> opens the separation coupling 304 and the coupling <B> 386 to positive engagement which is intended to assist it, so that the rotor <B> 312 </ B> can rotate freely with the <B> 305 </ B> moving mass element.

<B> A </ B> Figure <B> 6d, </ B> a further axial movement of the release device <B> 315 </ B> to its furthest position from the drive shaft < B> 303 </ B> causes <B> to </ B> the <B> d </ B> state in which couplings 304, <B> 386 </ B> are still open as a mating joint separation, and the starter coupling <B> 306 </ B> is closed by the release device <B> 315. </ B>

The appended claims <B> to </ B> the present application are wording proposals, without prejudice to obtaining extended <B> plus </ B> patent protection. The plaintiff reserves the right to claim further combinations of features which heretofore have only been disclosed in the description and / or the drawings. References in the subclaims relate to further development of the subject matter of the main claim by the features of the respective subclaims; they should not be regarded as a renouncement of obtaining object-independent protection from the combinations of features of the relevant subclaims.

Since the subject-matter of the subclaims may constitute independent and independent inventions taking into account the state of the art <B> to </ B> the priority date, the plaintiff reserves the right to be the object of independent claims <B> or </ B> of divisional applications. The objects of the under-claims may also contain autonomous inventions, which represent a configuration independent of the objects of the preceding subclaims.

The exemplary embodiments should not be understood as a limitation of the invention. Rather, many alterations and modifications are possible within the scope of this publication, in particular variants, elements and combinations and / or materials which those skilled in the art can for example <B>, </ B> in to achieve the purpose, deduce by combination or transformation of the particulars or elements <B> or </ B> process steps described in the general description and the embodiments as well as the claims and contained in the drawings, and which lead by combinable features <B> to </ B> a new object or <B> to </ B> new process steps or process step sequences, insofar as they relate to manufacturing processes, checking and machining.

Claims (1)

<U> CLAIMS </ U> <B> 1. </ B> Drive train, in particular for vehicles, which consists of at least one drive unit, a moving mass element <B> (5) </ B> and an output unit, wherein: the moving mass element can be coupled to the drive unit by means of a separation coupling and be coupled to the output unit by means of a starting or switching coupling (6), and the at least two couplings which may each be in a state open and closed coupling are operated by means of a single release arrangement <B> to axially movable release member, characterized in that the coupling states of a coupling (4, <B> 6) </ B> can be established independently of the coupling state of the other coupling. 2. Drive train according to claim 1, characterized in that at least one of the two couplings is a friction coupling which comprises: a pressure plate B> (130, 131) </ B> moving axially under the effect of the disengagement element in opposition <B> to </ B> an energy accumulator <B> to </ B> axial effect which determines friction contact, an axially fixed movable mass member including at least one friction contact surface, as well as a coupling disk <B> (133, 139) </ B> which is connected in engagement <B> to </ B> rotation <B> to </ B> the drive shaft or <B> to </ B> the output shaft and that can be brought axially into frictional contact by means of friction linings between frictional contact surfaces of the pressure plate and the moving mass element. <B> 3. </ B> Drive train according to claim 1, characterized in that the operation of the couplings (104, <B> 106) </ B> intended <B > to </ B> activate all the coupling states by means of a continuous axial displacement cycle of the displacement device <B> (15). </ B> <I> 4. </ I> Drive train <B> (1) </ B> according to any one of the preceding claims, characterized in that the release arrangement <B> (16) </ B> is operated manually or automatically. <B> 5. </ B> Drive train (1) according to any one of the preceding claims, characterized in that the operation of the disengagement arrangement <B> (16) </ B> takes place hydraulically, pneumatically, electrically or by a combination of these. <B> 6. </ B> Drive train according to any one of the preceding claims, characterized in that the clearance arrangement <B> (16) </ B> is arranged around the output shaft <B> (8). </ B> <B> 7. </ B> The drive train as claimed in any one of the preceding claims, characterized in that the axially movable release device <B> (15) < / B> is arranged around the output shaft <B> (8). </ B> <B>. </ B> Drive train according to any one of the preceding claims, characterized in that a drive unit (2), for example a combustion <B> engine, is indirectly connectable or directly <B> to </ B> the output shaft <B> (8) </ B> by means of one of the couplings. <B> 9. </ B> Drive train according to any one of the preceding claims, characterized in that a rotor (12) of an electric machine <B> (13) </ B> is attached in engagement <B> to </ B> rotate <B> to </ B> the outer periphery of the moving mass element. <B> 10. </ B> Drive train according to one of the preceding claims, characterized in that the separating coupling (4) intervenes between the drive shaft <B> (3) </ B> and the moving mass element. <B> 11. </ B> Drive train according to any one of the preceding claims, characterized in that the switching coupling <B> (6) </ B> intervenes between the moving mass element and the output shaft <B> (8). 12. A drive train according to any one of the preceding claims, characterized in that the pressure plate <B> (131) </ B> of the switching coupling is axially movable by means of the opposition device <B> to </ B> the axial effect of an energy accumulator <B> (159) </ B> which clamps the plate of pressing the switching coupling on the movable mass element to form the <B> to </ B> friction engagement, and that is how the switching coupling is maneuvered. <B> 13. </ B> A drive train according to any one of the preceding claims, characterized in that a coupling cover <B> (161) connected <B> to </ B> pressure plate of the separation coupling is axially movable by means of the release device in opposition <B> to </ B> the axial effect of an energy accumulator <B> (158) </ B> which closes the pressure plate of the separation coupling on the movable mass element to establish the engagement <B> to </ B> friction, and in this way that the separation coupling is maneuver. 14. Drive train according to any one of the preceding claims, characterized in that the switching coupling is operated by means of the release device by axially biasing arms <B> (162) </ B> of the energy accumulator <B> (159) </ B> oriented radially inwardly, for example spring tongues <B> to </ B> disc from a spring <B> to </ B> disc. <B> 15. </ B> Drive train according to any one of the preceding claims, characterized in that the separation coupling is operated by means of the release device by axially biasing arms <B> (169) </ B> of the coupling cover <B> (161) </ B> oriented radially inwards. <B> 16. </ B> Drive train according to any one of the preceding claims, characterized in that the radially inwardly widened coupling cover arms are biased by the disengagement device, while the arm <B> (162) </ B> widened radially inwardly of the energy accumulator of the switching coupling are interposed axially. <B> 17. </ B> Drive train according to any one of the preceding claims, characterized in that the arms <B> (162) </ B> widened radially towards the inside of the accumulator. <B> (159) </ B> energy of the switching coupling penetrates axially <B> to </ B> through recesses provided in the widened arms radially inwardly of the coupling cover. <B> 18. </ B> Drive train according to any one of the preceding claims, characterized in that, starting from a state of rest of the release device in the direction of its axial displacement, the arms <B > (162) </ B> oriented radially inward of the energy accumulator of the switching coupling are solicited first and the arms <B> (169) </ B> oriented radially towards the inside the coupling cover are then solicited. <B> 19. </ B> Train according to <B> 1 '</ B> any of the preceding claims, characterized in that the switching coupling <B> (106) </ B> is clear firstly during an axial displacement of the release device in the direction of the drive unit (2). 20. Drive train according to any one of the preceding claims, characterized in that, when the switching coupling <B> (106) </ B> is open, the disengagement device opens the separation coupling by axial displacement of the housing <B> (161) </ B> coupling towards the drive unit. 21. Drive train according to any one of the preceding claims, characterized in that it is an axial displacement of the housing <B> (161) </ B> coupling towards the drive unit which closes the switching coupling <B> (106), </ B> when the switching coupling and the separation coupling are both open. 22. Drive train according to any one of the preceding claims, characterized in that the frictional contact between the friction plate support (140) of the pressure plate and the friction contact surface <B> (135) </ B> of the moving mass element of the switching coupling results, when the separation coupling is open, of a force play of energy accumulators designed to stress the pressure plates of the coupling switching and separation coupling. <B> 23. </ B> Drive train according to any one of the preceding claims, characterized in that the axial effective constant of energy accumulator, for example the elastic constant of the energy accumulator < B> at </ B> axial effect of the separation coupling (104) is greater, given the lever ratios, <B> to </ B> than that of the energy accumulator <B> (159) </ B> of the switching coupling. A drive train according to any one of the preceding claims, characterized in that the coupling cover (B) (161) is connected to the pressure plate of the separation coupling by means of studs. <B> (167) </ B> threads of axial extension, distributed over the periphery and passing through the movable mass element. <B> 25. </ B> Drive train according to any one of the preceding claims, characterized in that the threaded studs <B> (167) </ B> are arranged radially <B> to </ B> outside the pressure plate <B> (131) </ B> of the switching coupling. <B> 26. </ B> Drive train according to any one of the preceding claims, characterized in that the threaded studs are screwed to the pressure plate <B> (130) </ B> and / or the cover <B> (161) </ B> mating. <B> 27. </ B> Drive train according to any one of the preceding claims, characterized in that the two pressure plates <B> (130, 131) </ B> are arranged <B> to < / B> pretty much on the same periphery. <B> 28. </ B> Drive train according to any one of the preceding claims, characterized in that at least one of the couplings (104, <B> 106) </ B> is equipped with a surface of conical friction (130a, 134). <B> 29. </ B> A drive train according to any one of the preceding claims, characterized in that the separation coupling comprises conically shaped friction surfaces (130a, 134) such as the small radius of the Frustoconical friction surfaces are oriented towards the unit of the drive unit (2). <B> 30. </ B> Drive train according to any one of the preceding claims, characterized in that an axially fixed support plate is formed of at least one flange element <B> (390) < / B> connected to the rotor and widened radially inwards, to form at least one coupling, in that the support plate is supported by means of an energy accumulator <B> to </ B> effect axial to at least one component which is connected to the rotor and forms at least one bearing surface <B> (389b) </ B> for this accumulator and that the coupling disk <B> to </ B> friction linings is arranged axially between the pressure plate and the support plate. <B> 31. </ B> Drive train according to any one of the preceding claims, characterized in that the component which forms at least one bearing surface <B> (389b) </ B> forms the surfaces <B> (389b, </ B> 389c, <B> 389d) </ B> for the energy accumulators of both couplings. <B> 32. </ B> A drive train according to any one of the preceding claims, characterized in that the component is a flange element <B> which widens radially inwards and has two bearing surfaces (389c, <B> 389d) </ B> arranged on different peripheries, in that the energy accumulator <B> (359) </ B> rests on a surface radially external <B> or </ B> radially inner depending on the position of the release device, and in that a bearing surface provided on the pressure plate is provided radially between the two bearing surfaces of the element flange. <B> 33. </ B> A drive train according to any one of the preceding claims, characterized in that the energy accumulator <B> (359) </ B> is arranged substantially unrestrained when the coupling is open and in that it clamps the pressure plate against the support plate <B> (391) </ B> during a maneuver in each of the two axial directions. 34. Drive train according to any one of the preceding claims, characterized in that the energy accumulator <B> (359) </ B> establishes two closed states of coupling according to the axial position of the device release plate <B> (15). </ B> <B> 35. </ B> A drive train according to any one of the preceding claims, characterized in that the coupling <B> (306) </ B> which shows the two closed coupling states according to the position of the release device <B> (15) </ B> is the starting or switching coupling. <B> 36. </ b> A drive train according to any one of the preceding claims, characterized in that the disengagement device intervenes axially on an arrangement <B> with </ B> levers to urge the two couplings of which one has two closed coupling states depending on the axial position of the disengagement device, and in that the lever arrangement consists of a first lever system (B) (365) </ B>. axially biasing the energy accumulator of a switching coupling and biasing the energy accumulator to <B> to </ B> generating a first closed coupling state of a second coupling, and a second <B> (368) </ B> lever system for generating the second, closed coupling state of the second coupling. <B> 37. </ B> A drive train according to any one of the preceding claims, characterized in that the separation coupling (304) which consists of a friction coupling is bypassed by means of a coupling <B> (386) to </ B> positive engagement. <B> 38. </ B> A drive train according to any one of the preceding claims, characterized in that the <B> (386) positive engagement coupling is coupled by means of the arrangement <B> (361) </ B> of levers, particularly by means of the lever system that maneuvers the coupling to bypass. <B> 39. </ B> A drive train according to any one of the preceding claims, characterized in that the <B> coupling (386) to positive engagement and the separation coupling (304) ) separate the drive unit from the moving mass element. 40. Drive train according to any one of the preceding claims, characterized in that the positive engagement coupling <B> (386) is disengaged during axial movement of the disengaging device after opening. the <B> (308) </ B> start coupling and before opening the separation coupling <B> to </ B> friction. 41. Drive train according to any one of the preceding claims, characterized in that the lever systems <B> (365, 368) </ B> are axially movable relative to each other <B> to </ B > the other. 42. Drive train according to any one of the preceding claims, characterized in that, starting from a basic state in which the two couplings are closed, the first system of levers <B> (365) </ B > is firstly operated during an axial displacement of the release device and opens the coupling <B> to two closed coupling states, and in that the first lever system is moved axially on the second lever <B> (368) </ B> system and the second lever system is not moved axially. 43. Drive train according to any one of the preceding claims, characterized in that the two lever systems comprise at least each an axial stop (366a, <B> 366b) </ B> which operates on the lever in engagement <B> to </ B> force in the axial direction for operating the energy accumulators <B> (358, 359). </ B> 44. A drive train according to any one of the preceding claims, characterized in that the two energy accumulators are solicited <B> (358, 359) </ B> by means of one of the two stops (356a, <B> 356b). </ B> 45. Drive train according to any one of the preceding claims, characterized in that one of the two energy accumulators <B> (358) </ B> is biased by the stop (366a) by interposing a transmission arrangement to lengthen the clearance path. 46. Drive train according to one of the preceding claims, characterized in that the transmission arrangement consists of two radially inwardly widened flange members connected to one another. the other in engagement <B> to </ B> force, and in that the first flange member <B> (319) </ B> is suspended in the energy accumulator <B> to </ B> > axial effect of the pressure plate that it solicits and the second flange element <B> (368) </ B> rests on the stop. 47. Drive train according to any one of the preceding claims, characterized in that the axial connection (319a) of the flange members <B> (319, 368) </ B> is provided on the inner periphery thereof. . 48. Drive train according to any one of the preceding claims, characterized in that the return of the flange elements <B> (319, 368) </ B> is effected by means of another energy accumulator. (319a) <B> to </ B> axial effect. 49. Drive train according to any one of the preceding claims, characterized in that the element <B> (305) </ B> of moving mass is housed <B> at </ B> rotation on the shaft <B> or </ B> on a component (394) connected to it in a fixed manner. <B> 50. </ B> Drive train according to any one of the preceding claims, characterized in that the rotor <B> (312) </ B> is housed <B> at </ B> rotation on the drive shaft or a component (394) which is fixedly connected to the drive shaft. <B> 51. </ b> A drive train according to any one of the preceding claims, characterized in that the component is a flange (394) connected to the drive shaft. <B> 52. </ B> Drive train according to any one of the preceding claims, characterized in that the support plate <B> or </ B> the rotor is <B> housed </ B> radially <B> to </ B> the outside of screwing <B> (351) </ B> of the flange (394) with the drive unit. <B> 53. </ B> Drive train according to any one of the preceding claims, characterized in that the flange (394) receives in a fixed manner <B> to </ B> rotation the drive disk < B> (339) to </ B> friction linings for the separation coupling. 54. Drive train according to one of the preceding claims, characterized in that a damping <B> (333b, 133b) </ b> of torsional oscillations is provided in the force path between the drive shaft drive <B> (103) </ B> and the output shaft. <B> 55. </ B> Drive train according to any one of the preceding claims, characterized in that the damping <B> (333b, 133b) </ B> of torsional oscillations is provided in the flow of force between the start coupling <B> (306, 106) </ B> and the output gear. <B> 56. </ B> Drive train according to any one of the preceding claims, characterized in that the damping <B> (133b, 333b) </ b> of torsional oscillations is provided in the coupling disc <B> (133) <B> to </ B> friction linings. <B> 57. </ B> Drive train according to any one of the preceding claims, characterized in that the shock absorber <B> (290) </ B> of torsional oscillations is provided in the path of force between the drive shaft <B> (203) </ B> and the starter coupling. <B> 58. </ B> A drive train according to any one of the preceding claims, characterized in that the shock absorber <B> (290) </ B> of torsional oscillations is a split flywheel, which consists of at least two moving masses <B> (291, 292) to </ B> rotation with respect to <B> to </ B> the other in opposition <B> to </ B> l effect of energy accumulators intervening in peripheral direction. <B> 59. </ B> A drive train according to any one of the preceding claims, characterized in that one of the moving masses <B> (291, 292) </ B> is the element <B > (205) </ B> moving mass or rotor. <B> 60. </ B> Drive train according to any one of the preceding claims, characterized in that the divided flywheel comprises a primary movable mass <B> (291) </ B> which is connected in a fixed manner <B> to </ B> the drive shaft and is movable <B> to </ B> rotation relative to <B> to </ B> a secondary moving mass <B> (292, 205, </ B> 212) which is housed <B> at </ B> ro tation, in opposition <B> at </ B> the effect of energy accumulators and in that the moving mass element or the rotor of the secondary mobile mass can be introduced into the circuit by means of the separation coupling. <B> 61. </ B> Drive train according to any one of the preceding claims, characterized in that the element <B> (205) </ B> of moving mass or the rotor and the secondary mobile mass <B> (292) </ B> are housed separately from one another on a flange permanently connected <B> to the </ B> drive shaft. <B> 62. </ B> Drive train according to any one of the preceding claims, characterized in that the coupling disk <B> (239) </ B> of the separation coupling is connected from Fixed way <B> to </ B> a <B> (232) </ B> disk element connected to <B> to the secondary mobile mass. <B> 63. </ B> A driving train according to any one of the preceding claims, characterized in that the energy accumulators <B> (293) </ B> of the divided flywheel are arranged <B> to </ B> approximately <B> to </ B> a radial height equal <B> to </ B> that of the rotor (212). 64. Drive train according to one of the preceding claims, characterized in that the double coupling (204, <B> 206) </ B> is equipped for at least one coupling (204, <B> 206) < / B> of a friction compensation device friction compensation. <B> 65. </ B> Drive train according to any one of the preceding claims, characterized in that the wear compensation device intervenes for the two couplings (204, <B> 206). </ B > <B> 66. </ B> A method of operating a drive train, particularly for a vehicle, which consists of at least two assemblies connectable to a tree by means of at least two couplings <B> to </ B> release assembly, wherein coupling states of first and second couplings (4, <B> 6) </ B> are manipulated by means of an axially movable release assembly <B> (16) to </ B>, characterized in that the clearance assembly makes it possible to establish the following four coupling states: a) first closed coupling, second coupling, closed, <B> <I> b) </ I> </ B> </ B> </ B> </ B> </ b> </ b> </ b> </ b> </ b> </ b> <B> d) </ B> first open coupling, second closed coupling <B> 67. </ B> The method of claim 66, characterized in that the coupling states are sequentially switched in the following order: a) first coupling (4) closed, second coupling <B> (6), </ B> closed, <B> b) </ B> first closed coupling, second coupling open, <B> C) </ B> first open coupling, second open coupling, <B> d) </ B> first open coupling, second closed coupling <B> 68. </ B> The method of claim 67P characterized in that a displacement <B> to </ B> back and forth of the continuously moving axial disengagement device sequentially switches the coupling states in the following order: a) first clutch (4) closed, second clutch < B> (6), </ B> closed, <B> b) </ B> first closed coupling, second open coupling, <B> C) </ B> first open coupling, second a open coupling, <B> d) </ B> first open coupling, second closed coupling <B> 69. </ B> Method according to claim 66, </ b> or <b> 67, </ b> characterized in that the first coupling (4) is a separating coupling which couples between them in engagement <B> to </ B> forces both assemblies and in that the second coupling <B> (6) </ B> is a starter coupling which couples to an output shaft the assemblies as a function of the coupling state of the separation coupling. <B> 70. </ B> A method according to any one of the preceding claims, characterized in that the two assemblies are a combustion engine (B) and an electric machine (B). ). </ B> <B> 71. </ B> A method according to any one of the preceding claims, characterized in that starting from a starting point <B> where </ B> the two couplings (4 , <B> 6) </ B> are closed, the operation of the couplings Is carried out in a direction in opposition <B> to </ B> the axial effect of at least one accumulator <B> (158, 159 ). </ B> <B> 72. </ B> A method according to any one of the preceding claims, characterized in that the operation of the couplings (4, <B> 6) </ B> is carried out by traction or pushing the release device <B> (15). </ B>