DE19618864C2 - Torsional vibration damper with a balancing mass - Google Patents

Description

The invention relates to a torsional vibration damper according to the Oberbe handle of claim 1.

From DE 44 26 317 A1 is a torsional vibration damper with one drive-side transmission element in the form of a flange on the crankshaft ren traction sheave or a flywheel attached to this and one drive-side transmission element in the form of at least parts of a clutch disc known with the flywheel friction clutch. On the clutch disc are control means for elastic elements of a damper tion device provided by which torsion initiated on the drive side vibrations are dampened before being transmitted to the output side. On the traction sheave, that is to say on the drive-side transmission element, are Ta rule provided, each having a recess for receiving an off Equal flywheel mass, which are disc-shaped, in their Contact area with the assigned guideway of the respective recess  accordingly has a curvature which occurs when a torsional vibration is initiated a rolling motion of the balance mass along this guide railway enables. The guideway in turn has a greater curvature radius as the compensating flywheel mass, the rolling motion of the last to enable named.

The balancing masses in the respective recordings of the pockets the rotation of the torsional vibration damper under the action of the flee force pushed radially outwards and from this position when opening a gate tional vibration deflected in the circumferential direction. When the torso is weakened ons oscillation return the balancing masses to their middle position back.

Such a torsional vibration damper is usually called "Solomon Tilger "denotes and has the advantage that the balancing masses out visible their deflection speed from speed changes on which the off Equal flywheel receiving transmission element are dependent on the Torsional vibration damper is therefore effective depending on the speed. In order to can torsion vibrations of a certain order, with internal combustion Machines with four cylinders, preferably of the second order, for certain Greatly reduce amplitude sizes by a certain amount, however there is no possibility of influencing vibrations of other orders.

In addition, there is an arrangement of the balancing mass on the drive side gen transmission element the following problem: On this transmission element are torsional vibrations initiated by the crankshaft at full strength transferred to the balance flywheel so that this to reduce the initiated torsional vibration relatively massive and thus large have to be. This makes the entire torsional vibration damper heavy and can have undesirably large dimensions.  

DE 36 43 272 A1 describes a torsional vibration damper which one flywheel as the drive-side transmission element and one relative for this purpose rotatable clutch disc arranged on a gear shaft in a rotationally fixed manner as the output-side transmission element, the latter to Control means for elastic elements of a damping device. The Clutch disc is over a clutch with a balancing swing mass connected, which rotates freely relative to the actual flywheel is stored and due to their inertia when initiating a torsion vibration builds up a section modulus.

The balance flywheel is equipped with spring-loaded balance weights provided that experience a deflection from their rest position depending on centrifugal force. The balance flywheel is effective depending on the speed, however it is due to a spring connection with one of the transmission elements le only in sufficient frequency ranges determined by the springs kung functional, but can fail in other frequency ranges.

DE 43 03 303 C1 is the release area of a torsional vibration damper, which is provided with a balance flywheel. The Balance flywheel mass has a clutch, which with the release is in operative connection, so that the balancing mass when disengaging is uncoupled from the output side. This is beneficial because of the twist Number adjustment of the gear shaft to the corresponding speed, which is the only one corresponding gear, done quickly by the transmission synchronization for this purpose, the lowest possible inertia mass on the output side should be realized. A disadvantage of the torsional vibration damper according to the PS, however, is that he, only at a be by spring elements of the balance flywheel tuned natural frequency is effective.

A flywheel mass is known from US Pat. No. 5,295,411, which in a more number of circular recesses each a circular balancing swing takes up mass, the diameter of the latter smaller than that  the recess is. This flywheel is also a "Solomon absorber".

DE 36 30 398 C2 has a torsional vibration damper with a drive-side transmission element and a rotatable relative thereto described drive-side transmission element, each of these transmissions gung elements a flywheel is assigned. Such a torsional vibration attenuators are suitable for filtering a complete frequency range, that is to dampen amplitudes of different orders, but are special disturbing amplitudes of a certain order are not so effective suppressable, as would often be required.

The invention has for its object a torsional vibration damper develop that from a drive, such as an internal combustion engine machine, delivered vibrations with the smallest and lightest possible equal flywheel mass can be filtered out as far as possible.

This object is achieved by the characterizing part of claims 1 or 2 specified features solved.

Due to the special design of a torsional vibration damper At least one balance flywheel creates an overall facility at which has the advantages of being effective as a filter for a complete frequency range men torsional vibration damper with the advantage of balancing swing masses to counteract a vibration of a certain order, can be combined is. Due to the design of the transmission element with at least one Recess that at least in its contact area with the at least one Balance flywheel has a guide track on which the off Equal momentum mass, which has a curvature when introducing a torso ons oscillation can carry out a rolling motion, contains this transfer supply element a so-called "Salomon Tilger", in which an increased Aus steering speed on the transmission element always an increased deflection speed of the balance mass from its rest position.  

The balance flywheel mass can be dimensioned such that it at Vibrations of a certain order is effective, such that the Amplitude size of this vibration reduced by a certain amount becomes.  

Furthermore, the damping behavior of this "Salomon-Tilger" from geometri conditions, such as the respective bend of the guideway in relation to the curvature of the balancing mass in the contact area with the The guideway and the oscillation angle of the compensating flywheel be Right.

The Salomon absorber is particularly easy to design if both the management path on the recess of the transmission element and the curvature the balance flywheel mass at least in the mutual contact area are circular, the guideway to ensure a Movement of the balance mass with a larger radius than that Balance flywheel is formed.

The last-mentioned constructive measure can result in that, if when the torsional vibration damper is stopped, no more centrifugal force on the Balance mass is effective, this under the action of gravity falls down to the other end of the recess. When restarting the Torsional vibration damper, the balance mass is radial accelerated outside until it is in the corresponding area of the guideway impacts. This problem is eliminated by having the guideway on according to the saying, a path limitation is assigned when the gate is stopped sionsschwingungsdämpfers a falling of the balancing mass and un prevented the effect of weight.

By arranging the Salomon absorber according to the invention in a torsion Vibration damper in which each transmission element has its own Balance mass is assigned, the ability of the Salomon-Tilger, Amplitu dampen that of a certain order with an excellent filter combined, so that a particularly good decoupling quality arises.

In a further claim, the combination of the Salomon absorber with a conventional clutch, which has only a flywheel, shown  an advantageous constructive solution is shown to compensate Flywheel mass through an additional clutch from the output side loosen the support element as soon as the friction clutch is disengaged.

The following is an embodiment of the invention with reference to a drawing explained in more detail. It shows:

Figure 1 is a longitudinal section through a half representation of the flywheel device with a ring gear acting as a ring gear and a planet gear, with a recess in the output-side flywheel for receiving a compensating flywheel circular cross section is provided.

Fig. 2 as shown in Figure 1, but with a balance flywheel with wesentli Chen semicircular cross-section.

Fig. 3 is as Figure 1 but with a limited radial direction in recess.

Fig. 4 like Figure 1, but with inclusion of the balance flywheel in Na Na disc.

Fig. 5 shows a torsional vibration damper with only one flywheel with a housing for receiving the balancing flywheel.

The torsional vibration damper shown in Fig. 1 has a drive-side transmission element 1 , which is formed with a flywheel 2 with an after ra dial outside primary flange 3 , which has in the peripheral area egg NEN axial edge 4 , on which a with a starter not shown zel in Engagement standing ring gear 5 is placed. The axial edge 4 carries a sealing plate 6 which projects radially inwards. Together with the axial edge 4 and the primary flange 3, this delimits a grease space 8 , in which elastic elements 10 of a damping device 11 extending in the circumferential direction are arranged in the radially outer region. The elastic elements 10 can be acted upon at one end by control elements 12 on the primary flange 3 , while at the other end they are supported on fingers 14 of a hub disc 15 projecting radially outwards, which acts as a ring gear 17 of a planetary gear and has a secondary hub 16 for receiving it at its radially inner end a storage 18 . The latter in turn carries a primary hub 20 of the primary flange 3 . Seen in the axial direction, the primary hub 20 extends, starting from the primary flange 3 in the direction of the hub disk 15 , while the secondary hub 16 extends from the latter in the direction of the primary flange 3 .

By the bearing 18 , the hub disc 15 is rotatably arranged on the drive-side flywheel 2 , and connected via rivets 22 with a second flywheel 23 , which is effective together with the hub disc 15 as a transmission element 24 abtriebsseiti ges. Radially close outside of the bearing 18 , the hub disc 15 is provided with a mounting opening 26 through which fastening means 27 can be inserted. The fasteners hold with their head 28 a seal 30 through which the grease chamber 8 is sealed radially inwards. The torsional vibration damper can be fastened to a crankshaft (not shown) of an internal combustion engine via the fastening means 27 .

The primary flange 3 has at least one in the direction of the hub disc 15 before jumping bearing shoulder 31 , on each of which a Pla netenrad 33 is arranged via a needle bearing 32 , which is in engagement with the ring gear 17 via its teeth 35 .

A recess 38 is provided in the second flywheel 23 on its side facing the first flywheel 2 , which, as the view along the line AA alongside FIG. 1 shows, has a radius R with a radius and accommodates a compensating flywheel 40 . which is formed by a roller of circular cross-section with radius r. In operation of the torsional vibration damper, under the action of the centrifugal force which occurs due to a rotation about the axis 41 , the balancing flywheel 40 is brought into the position shown in FIG. 1, where the initiation of a torsional vibration which accelerates or decelerates the second flywheel mass 23 has the consequence, a deflection of the balancing swing mass 40 from its shown rest position in the clockwise direction or in the opposite direction results in this. The outer periphery of the recess 38 acts here with a guide track 42 for the compensating flywheel, while it is formed on the basis of their circular cross-section along its entire circumference with a curvature 44, and can roll along a contact area 45 on the guide track 42nd The moment of inertia of the second flywheel 23 is apparently increased by the compensating flywheel mass 40 , since a translation becomes effective with the curvature 44 of the compensating flywheel mass 40 on the guideway 42 during the rolling movement. Due to the equalizing flywheel 40 in the recess 38 of the flywheel 23 , the latter is effective as a "Salomon damper", on the deflection speed of which, for example, the dimensioning of the radius r of the compensating flywheel mass 40 compared to the radius R of the recess 38 , the angular deflection between the compensating flywheel mass 40 and second flywheel 23 and the steering acceleration from the second flywheel 23 due to an initiated torsional vibration. The Salomon damper is effective according to the general differential equation + f (R, r, a) Ω ² ψ = 0, where a is the distance between the contact area 45 of the compensating flywheel mass 40 and the guideway 42 of the second flywheel mass 23 with respect to the axis of rotation 41 of the torsional vibration damper minus the radius r of the curvature 44 of the balance flywheel 40 and Ω indicates the excitation speed at the - second flywheel mass 23 . The deflection speed ω of the compensating flywheel mass is a function of the root of R, r and a, multiplied by Ω, this root representing the order n of the amplitude to be damped by the Salomon damper.

Fig. 2 shows a balance flywheel 40 with a substantially semicircular cross-section, the contact area 45 between the guide track 42 and the curvature 44 is dependent on the angular extent of the latter. Otherwise, the design of the torsional vibration damper of FIG. 2 corresponds to that of FIG. 1st

When the torsional vibration damper described above is at a standstill, the compensating flywheel mass 40 falls down under the action of gravity, and accelerates again during operation due to the action of centrifugal force, where the compensating flywheel mass 40 impinges on the guideway 42 . This is prevented in the execution of the recess 38 shown in FIG. 3, since when the torsional vibration damper is at a standstill, the balancing mass 40 is prevented from falling downward, namely by the radially inner edge 48 effective as Wegbe edge 47 of the recess 38 .

Fig. 4 shows yet another embodiment, wherein the balancing mass 40 is arranged in a recess 50 of the ring gear 17 . Since this ring gear 17 is fixedly connected to the second flywheel 23 because of its one-piece construction with the hub disc 15 , the other accommodation location of the compensating flywheel mass 40 does not cause any change in the functional behavior of the torsion vibration damper compared to the previously described exemplary embodiments.

Fig. 5 shows another embodiment of the torsional vibration damper according to the invention, which has only a single flywheel 52 as the drive-side transmission element 1 . In its radially central region, this has a space 53 in which a housing 56 for the compensating flywheel mass 40 is rotatably mounted with respect to the flywheel mass 53 via a bearing 54 . The housing 56 has a carrier 55 for a friction lining 57 in the radially inner region, via which the housing 56, depending on the axial position of an effective as a transmission-side transmission element 24, coupling disk 60 is in a non-positive connection to it or is detached from it, that is , depending on whether the friction clutch 62 is engaged or disengaged. In the engaged state, the clutch disc 60, and in particular the cover plate 59 on the left in FIG. 5 thereof, is held by the pressure spring 64 of the friction clutch 62 in contact with the friction lining 57 of the housing 56 , so that it is rotatably attached to the clutch disc 60 and therefore not to the clutch shown transmission shaft is connected. It follows that the balance flywheel 40 is coupled in motion during the operation of the friction clutch to the gear shaft, while after moving after the positive connection of the housing 56 to the clutch disc 60 is canceled, the connection between the balance flywheel 40 and the gear shaft is released is. The background here is that to protect synchronizers in the transmission, the mass hanging on the gear shaft le should be as small as possible. On account of the friction lining 57 formed on the carrier 55 , a shift clutch 65 is accordingly assigned to the balance flywheel mass 40 .

Claims (2)

1. Torsional vibration damper with a drive-side transmission element and a relatively rotatable output-side transmission element, of which at least one control means for elastic elements has a damping device, and of which at least one compensating flywheel mass is assigned, at least one of the transmission elements having at least one recess Inclusion of the at least one compensating flywheel mass, which is provided at least in its contact area with a guideway of the recess with a curvature for a rolling movement of the compensating flywheel mass along the guideway when torsional vibration is introduced, characterized in that the drive-side transmission element ( 1 ) has a first swing mass ( 2 ) and the output-side transmission element ( 24 ) is assigned a second flywheel ( 23 ), of which the second flywheel mass ( 23 ) has the recess ( 38 ) for opening balancing swing mass ( 40 ). 2. Torsional vibration damper with a flywheel as the drive-side transmission element and a clutch disc as the output-side transmission element, of which at least one control means for elastic elements of a damping device and of which a balancing flywheel mass is received in such a way that it can be released by a clutch when disengaging from the driven side is, wherein the compensating flywheel receiving transmission element has at least one recess for receiving the at least one compensating flywheel, which is provided at least in its contact area with a guide path of the recess with a curvature for a rolling motion of the compensating flywheel against the guideway when a torsional vibration is initiated , characterized in that on the flywheel ( 52 ) a housing ( 56 ) provided with the recess ( 38 ) for the equalizing flywheel mass ( 40 ) rotatably r is arranged, which is releasably connected via the clutch ( 65 ) to the clutch disc ( 60 ).