DE3411090A1 - Damping device for taking up or compensating torsional impacts - Google Patents

Abstract

The invention relates to a damping device having at least two coaxially arranged centrifugal weights capable of limited relative rotation counter to the action of damping means. To improve functioning and increase the service life, at least two bearings are provided, one bearing serving to support a transmission shaft relative to one centrifugal weight and the other bearing serving to support the other centrifugal weight on the transmission shaft.

Description

Damping device for absorbing or compensating for rotary shocks

The invention relates to a damping device for absorbing or compensating for rotary shocks, in particular torque fluctuations of an internal combustion engine by means of at least two centrifugal masses which are arranged coaxially to one another and can be rotated to a limited extent against the action of damping means, one of which, first, with the internal combustion engine and the other, second, can be connected to the input part of the transmission.
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Such damping devices were z. B. for motor vehicles excited, the mentioned second flywheel with the transmission input shaft via a friction clutch is connectable. In the previously proposed damping devices of this type is limited rotatable mounting of the two centrifugal masses to each other one of the centrifugal masses via at least one bearing stored immediately on top of the other. Such

3411050

However, storage has that. Disadvantage that the bearing between two, only limited rotatable to each other Flywheels are provided between

in addition, torsional vibrations during ferry operation under load very high frequency and small amplitude occur, which are in the range of one degree and below. Both in plain bearings and in roller bearings, the effects caused by the vibrations Changes in the direction of rotation, that no proper lubrication and sliding or rolling movement in the bearing takes place. There is another disadvantage, which has a negative effect in particular in the case of roller bearings in that the high stresses between the rolling elements and rolling tracks are practically always at the the same places or in the same, very small areas of the camp's university, which means the material is overstressed at these points or in these areas. This overuse can lead to the rolling bodies working or pressing into the rolling paths, which is a results in rapid destruction of the bearing. The overstressing of the material can also do so cause particles to be released from the surface of the rolling bodies and / or the rolling paths, so that dimple-like depressions arise, which also result in the destruction of the rolling bearing to have.

The present invention was based on the object of eliminating the disadvantages mentioned and of creating a damping device which is particularly simple and can be produced economically and, moreover, an improved function as well has an increased service life.

According to the invention, this is achieved in a damping device of the type mentioned in the introduction, that at least two bearings are provided around the transmission shaft, the first for supporting the transmission shaft is used opposite the crankshaft and the second to support the second flywheel on the gear shaft. Such an arrangement of the bearings ensures that whenever a switch is made, that is, if the between damping device and transmission input shaft provided friction clutch is actuated, the inner bearing rings received on the gear shaft opposite the outer bearing rings on the respective centrifugal mass provided bearing rings twist considerably, since between the transmission input shaft and crankshaft of the internal combustion engine have a large speed difference is present during the switching process. This large relative rotation causes the bearing to become fat is circulated in the bearings, creating lubrication arises. Furthermore change with each switching process

the relative positions between the outer ring, rolling elements and inner ring, so that the stresses that occur over the entire scope of the bearing, at least over the life of the bearing be distributed approximately evenly. This significantly increases the service life of the bearings, since the stressed areas are much larger.

On the basis of the figure, which shows a damping device according to the invention partially in section, the invention is explained in more detail.

The device 1 shown in the figure for compensating rotary shocks has a flywheel 2 which is divided into two flywheel masses 3 and h . The flywheel 3 is fastened to a crankshaft 5 of an internal combustion engine (not shown in detail) by means of fastening screws 6. A friction clutch 7 is attached to the flywheel k by means not shown in detail. Between the pressure plate 8 of the friction clutch 7 and the flywheel mass k , a clutch disk 9 is provided, which is received on the input shaft 10 of a transmission, not shown in detail. The pressure plate 8 of the friction clutch 7 is in the direction of the flywheel k by a pivotably mounted on the clutch cover 11 -;

Disc spring 12 is applied. By actuating the friction clutch 7, the flywheel h and thus also the flywheel 2 can be coupled and uncoupled via the clutch disk 9 of the transmission input shaft 10. 5

A vibration damper 13 is provided between the two centrifugal masses 3 and h , which counteracts a relative rotation between the two centrifugal masses. The vibration damper 13 has energy accumulators in the form of helical springs 14, only one of which is visible, as well as friction means 15 »16 for damping the springs 14 over the circumference of the flywheel 3 is supported distributed axial projections 19 and fastened there by means of screws 20 is _0, the output part of the vibration damper 13 is formed by two, on both sides of the flange-like input member 17 provided sheaves 21, formed, which is connected via spacer bolts 23 at an axial distance to each other in a rotationally fixed are. The spacer bolts 23 simultaneously serve to fasten the output part, that is to say the two disks 14 and 22, to the flywheel 4.

In the disks 21, 22 and in the input part 17 are. Recesses 21 a, 22 a and 17 a introduced, in which the coil springs Ik are added. The recesses 21 a, 22 a and 17 a as well as the therein coil springs l4, viewed over the periphery of the vibration damper 13, angeornet and dimensioned such that a multi-stage damping characteristic is present ₀ The input part 17 also has arc-shaped recesses 24 through which the spacer bolts 2 3 protrude. The limitation of the relative rotation between the two centrifugal masses 3 and h is ensured by stopping the spacer bolts 23 at the end regions of the arcuate recesses 2h.

The two centrifugal masses 3 and k are mounted so that they can rotate to a limited extent relative to one another via a mounting 25. The bearing 25 has two roller bearings, which are two ball bearings 26 and 27 in the illustrated embodiment. The outer bearing ring 26 a of the bearing 26 is received in an annular groove which is formed by two shoulders or bores 28, 29 of the same diameter directed towards one another and which are introduced into the crankshaft 5 on the one hand and into the flywheel 3 on the other. The inner one

Bearing ring 26 b of the bearing 26 receives the bearing journal 10 a of the transmission input shaft 10, whereby the transmission shaft 10 is centered with respect to the crankshaft 5. On the pin 10 a of the transmission input shaft 10, in addition to the inner bearing ring 26 b of the bearing 26, the inner bearing ring 27 b of the bearing 27 is also arranged. The outer bearing ring 27 a of the bearing 27 carries the flywheel 4 so that it is centered on the transmission input shaft 10 via the bearing 27 so that it can rotate. For this purpose, the flywheel h has a bore 30 in which the outer bearing ring 27 a is firmly received and axially secured by a locking ring 31.

When the clutch 7 is engaged, there is no relative rotation between the outer and inner bearing rings 27 a, 27 b of the bearing 27, since the clutch disk Q does not have a torsional vibration damper. Between the outer and inner bearing ring 26 a, 26 b of the bearing 26, on the other hand, a limited relative rotation can take place, since the flywheel h and thus also the transmission input shaft 10, which is fixed against the action of the vibration damper 13, limits the flywheel 3 against the flywheel 3 The limited rotatability, however, is not sufficient to ensure proper lubrication of the bearing 26. When disengaged

Friction clutch 7 »that is, when the clutch disc 9 is released, the outer bearing rings 26 a, 27 a are rotated against the inner bearing rings 26 b, 27 b due to the speed difference between the transmission input shaft 10 and the crankshaft 5, so that in these states the lubrication the bearings 26, 27 takes place. Furthermore, this relative rotation, which takes place when the friction clutch 7 is open, ensures that when the friction clutch is re-engaged, the inner bearing rings 26 b, 27 b have changed their angular position relative to the outer bearing rings 26 a, 27 a «

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Claims (1)

LuK slats and Coupling construction GmbH Industriestrasse 3 P.O. Box 1360 0477 D 758O Bühl / Baden Claim /) Damping device for absorbing or compensating from torsional jolts, especially from torque fluctuations an internal combustion engine by means of at least two arranged coaxially to one another, against the Effect of damping means limits the rotatable masses, one of which, first, with the internal combustion engine and the other, second, can be connected to the input part of the transmission is, characterized in that at least two bearings (26, 27) are provided around the gear shaft (ίο) are, the first (26) serving to support the gear shaft (1O) with respect to the crankshaft (5) and the second (27) for mounting the second flywheel (4) on the gear shaft (1O).