DE10057822A1 - Vibration absorbing device in particular suitable for flexible coupling, comprising outer and inner ring accommodating fluid chambers with elastic walls - Google Patents

Abstract

An outer and an inner ring (2, 3) can be rotated in opposite directions around a rotation axis (1) and accommodate the absorbing elements in the space (13) formed between them. When the rings (2, 3) are rotated a friction surface (14) located at a friction body (4) is pressed against a spring element (11) fixed to the inner surface of both rings (2, 3) resulting in the deformation of the outer wall (7, 28) of a fluid chamber (5). The fluid is pressed into a compensating area (6) through a bore (8) provided at a rigid vertically positioned plate (8).

Description

The invention relates to a damping device for a torsionally flexible Clutch.

State of the art

Torsionally flexible couplings come in a variety of forms known. Torsionally flexible couplings are used in motor vehicles to dampen torsional vibrations during torque transmission, or from the auxiliary units driven by the crankshaft decouple. The susceptibility to vibrations is long Belt drives increased. Since the numerous secondary and auxiliary units such as water pump, power steering pump, air conditioning compressor and generator, the belt drives in almost all engines are getting longer these systems are for resonances caused by the engine be stimulated, become more vulnerable. By interposing a torsionally flexible coupling is an almost complete vibration engineering The belt drive can be decoupled from the crankshaft.  

In German patents DE 40 18 596, DE 44 04 311 and DE 44 00 564 for example, such torsionally flexible couplings are claimed, whose damping capacity is essentially ring-shaped Spring body made of elastomeric material is specified. This highly elastic elastomer parts connect the crankshaft with the Pulley and cause a in the entire speed range Decoupling. By "decoupling" the pulley from the The crankshaft shifts the resonance speed of the belt drive below the engine idling speed. The vibration amplitudes of the Auxiliary units are getting smaller. To this vibration engineering To achieve decoupling between the drive and output side, these are torsionally flexible couplings usually operated supercritically, d. H. to the The resonance speed of the vibratory system, formed from drive, clutch and driven aggregate. In doing so, comparatively large vibration amplitudes. These affect the lifespan of the affected components, especially the service life of the Belt drive, and also cause increased noise of the drive. One is therefore striving, especially in the area of Vibrational amplitudes occurring resonance speed as possible to dampen effectively.

Hydraulic damping engine mounts, for example from DE 31 40 783, DE 32 44 296 damping devices are known, the Effect on a throttled overflow of a damping fluid between a working chamber and a compensation chamber. Low-frequency, linear vibration movements of an engine can by flowing this damping fluid back and forth effectively be dampened. The overflow opening, i.e. H. Length and diameter of the  Connection pipeline and the fluid properties of the Damping fluid are the main tuning parameters of these Two-chamber engine mount.

Presentation of the invention

The invention has for its object a damping device for to specify a torsionally flexible coupling so that the vibration-damping properties of the clutch, especially her Ability to dampen large vibration amplitudes can be improved and maintain high operational reliability and availability of the coupling stay. The design of the damping device should be as possible simply into existing torsionally flexible couplings with ring-shaped Elastomer spring bodies can be integrated and characterized by low Mark up costs.

This object is achieved with a damping device for a torsionally flexible coupling with the technical characteristics of the Claim 1 solved. On advantageous embodiments of the invention refer to the subclaims.

The damping device according to the invention is formed by a outer ring and an inner ring that are spaced radially from each other enclose to form an annular gap and that around an axis of rotation are rotatably supported relative to each other, at least one in the annular gap the one of the rings fixed pressure body with a in Circumferential direction continuously projecting stop surface, at least two, bounded by elastic, deformable walls, with a Damping medium filled working chambers on the other of the rings  are defined, which are seen in both directions on both sides of the Extend pressure body in the annular gap and each with a assigned compensation chamber through at least one overflow opening in an operative connection, one in the annular gap on the other of the rings specified, arranged between the pressing bodies and working chambers Spring body, which by a relative rotation of the rings by the Stop surface in each case on the wall surface of a working chamber It can be pressed that the damping medium deforms the wall flows through the overflow opening into the associated compensation chamber.

An idea on which the invention is based assumes that from the Technology of hydraulically damping engine mounts known operating principle in which a throttled overflow of a damping fluid between one Working chamber and a compensation chamber is used in that to dampen a linear vibration in torsionally flexible couplings to dampen torsional vibrations. The invention suggests to dampen large vibration amplitudes at a torsionally flexible coupling an additional damping device use. This essentially consists of two in an annular gap working chambers arranged adjacent to a pressing body. According to the invention, there is a between the pressing body and the working chambers Spring body arranged. With a relative rotation of the rings, the Contact surface of the pressure body on the spring body and this again on the wall surface of a working chamber. The elastic wall of the The working chamber is deformed by the pressing, which with a Volume reduction goes hand in hand. The consequence of this is that the active or Damping medium from the working chamber through the overflow opening in the associated compensation chamber flows.  

In the event of a torsional vibration, adjacent to the pressure body or Working chambers lying in the spring body are actuated alternately. The Overflow opening bids a throttle section for the damping medium. The the torsional vibration is used for the overflow withdrawn. The amplitude of this torsional vibration is damped.

Of course, several working chambers and several can be in the annular gap Pressure body may be arranged. The only important thing here is that everyone Pressure body and the working chambers interacting with it each are attached to different rings, so that when a Torsional vibration alternately to a pressing body or Chambers arranged in the spring body experience a change in volume.

Torsionally flexible couplings consist of concentrically mounted rings, so that the components arranged in the annular gap of two rings Damping device in a simple manner in a torsionally flexible coupling can be integrated.

The damping device according to the invention forms an additional component to a torsionally flexible coupling. The operational security and the The damping device does not make the coupling available impaired. Seen in the direction of the axis of rotation depending on desired damping effect several damping devices in parallel be switched.

The limitation of the angle of rotation of the relative rotation can be by torsionally flexible coupling or by stops.  

The compensation chamber is preferably designed so that in Damping operation the displaced volume of the active medium without pressure can be included. So that the damping effect in Essentially determined by the fluid-carrying overflow path, d. H. through diameter, length and roughness of the throttle section. For the Manufacture of the damping device, it is favorable if the wall everyone Compensation chamber or working chamber by one in the annular gap circumferential ring hose is formed. The ring hose can be made of metal or be made of plastic.

It is very favorable with regard to the service life of the damping device, if the between the pressure body and compensation chamber intermediate spring body seen in the circumferential direction, kidney-shaped is formed with thickened end pieces, one to the pressing body has a concavely curved cam surface, and this, in the direction of one Working chamber seen steadily in a cam flank of the respective one End piece is formed continuously. In this way, the Relative rotation of the rings with continuously changing translation into one Pressure can be implemented in one of the working chambers. A sliding friction only arises between the stop surface and the concave Cam surface. Since the spring body and the working chambers each on same ring are fixed, there is only a pressing of the Spring body to the elastic wall but not to a sliding friction. The Damping effect can be a function of the angle of rotation due to the curvature the cam surface.

If the walls of the working chambers or the Compensation chambers through an annular hose running in the annular gap can be formed, the damping device at low cost  getting produced. It is advantageous if each working chamber and the your assigned compensation chamber by a rigid overflow plate are separated. The fluidic connection between the working chamber and assigned adjacent compensation chamber is marked by an or several overflow channels formed. Depending on the design and size of this Throttle sections can limit the damping behavior within wide limits be specified. The rigid overflow plate can be technically easily set by clamping from the outside in the ring hose.

Depending on whether torsional vibrations are already at a rest position or only after a limit amplitude is to be damped, it is from Advantage if the damping device is in a non-rotating state each cam flank with the stop surface a circumferential distance includes or touches them. The pressing body is preferably simpler Cam formed. Regarding low friction between Pressure body and spring body is advantageous if the pressure body is formed by a rolling element.

For the manufacture and maintenance of the damping device, it is from Advantage if the working chamber and / or the compensation chamber with a closable opening are provided for filling or venting.

The wall of each working chamber has a particular advantage with elasticity formed such that the damping medium when not pressed Press body through the elastic regression of the wall from the Compensation chamber through the overflow opening into the working chamber is recoverable.  

The equalizing chamber can thus take up volume without pressure are trained and the damping behavior is determined by the fluidic design of the overflow opening specified.

From a manufacturing point of view, it can be beneficial if the Wall of the working chamber, for example, the wall of the compensation chamber is formed at least in sections as a bellows. Depending on the The damping medium can provide the desired damping effect different substances can be formed, for example from a gas, one hydraulic fluid, a lubricant or a lubricant that is provided with a solid fine grain.

With a torsionally flexible coupling, at least one is advantageous Damping device provided. The damping device is advantageous in a functional parallel connection to a spring body Coupling arranged. In particular, if the spring body by a Is formed elastomer, the additional damping device in the Large oscillation vibrations occurring in the resonance range are effective dampen.

Brief description of the drawing

To further explain the invention, reference is made to the drawings taken in the figures different embodiments and the Arrangement of the damping device in a torsionally flexible coupling are shown schematically. Show it:

Fig. 1 is a side view of an embodiment in a partial representation,

Fig. 2 is a side view of a particularly preferred embodiment in a partial representation

Fig. 3 shows the arrangement of the damping device according to the invention in a torsionally flexible coupling.

Implementation of the invention

An embodiment of the invention shown in FIG. 1 in a partial view. The damping device comprises an outer ring 3 and an inner ring 2 , which surround one another at a radial distance in order to form an annular gap 13 . The two concentrically arranged rings 2 , 3 can be rotated relative to one another about an axis of rotation 1 . On one of the rings, in Fig. 1 ring 3 , a pressing body 4 is fixed. The pressing body 4 has a stop surface 14 which projects continuously in the annular gap 13 . A spring body 11 is arranged radially on the inside against the pressing body 4 . This spring or pressure body 11 is rotatably connected to the ring 2 and abuts an elastic wall 7 . The elastic wall 7 encloses the interior of a working chamber 5, or 5 'and a compensation chamber 6, respectively 6'. The working chambers 5 , 5 'and the compensation chambers 6 , 6 ' are filled with a damping medium. A rigid overflow plate 8 separates the working chamber 5 from the compensation chamber 6 . It is penetrated by an overflow opening 9 , which connects the two chambers in a fluid-conducting manner. A relative rotation of the rings 2 , 3 , in one of the directions shown by arrow 27 , causes the stop surface 14 to press on the spring body 11 , which is mounted in the manner of a balance beam and is connected to the interior of the rings 2 in a rotationally fixed manner. The spring body passes this contact pressure on to the elastic wall 7 of one of the working chambers 5 , 5 '. The volume of this working chamber is reduced and displaces the damping medium into the associated compensation chamber. The overflow opening 9 forms a throttle section, which demands hydraulic work from the flow process. This dampens the energy introduced by torsional vibrations. As shown in FIG. 1, the throttle section can be formed by a bore in the rigid overflow plate 8 . It is of course also possible to separate the working chamber and the equalizing chamber by means of a plurality of overflow plates 8 ', 8 ". In this way, the damping behavior can be predetermined within wide limits. On the part of the manufacturer, it is advantageous if the working chambers or the equalizing chambers are delimited by an annular gap 13 circumferential ring hose 28 , which is provided with an opening 22. In which the pressure surface 14 does not act directly but with the interposition of a resilient body 11 on the working chambers 5 , 5 ', there is no abrasive wear due to sliding friction long service life. FIG. 1 shows the working chambers and compensation chambers on the inner ring 2 and the pressing member 4 are fixed to the outer ring 3. a functionally equivalent damping effect can of course also by a construction achieved in the chambers of the outer rings and the pressing member 4 on the inside n of the rings is fixed.

In the preferred exemplary embodiment shown in FIG. 2, the pressing body 4 is formed by a roller body 19 which encloses a circumferential distance 15 with the cam surface 16 of the spring body 11 . The cam surface 16 is concavely curved and merges continuously into a cam flank 17 of an end piece 12 of the spring body. With a sufficiently large relative rotation of the rings 2 , 3 , depending on the direction of vibration 27 , the rolling element is pressed against the cam flank 17 and thus the elastic wall 7 of a working chamber 5 , 5 'is deformed. As already explained in FIG. 1, in this active state of the damping device, the damping fluid flows into an associated compensation chamber and draws energy when the torsional vibration flows over it. Due to the elasticity of the wall 7 , a reformation occurs when the spring body is not pressed on. That is, the change in shape imposed on the chamber wall automatically reverts to its original shape and damping fluid now flows in the opposite direction from the compensating chamber back into the working chamber.

FIG. 3 shows the arrangement of the damping device 10 in a torsionally flexible coupling 20 . In this torsionally flexible coupling 20 , the pulley 24 is decoupled from the internal hub ring 25 by the elastic spring bodies 21 and 21 '. The torsionally flexible coupling 20 essentially consists of rings arranged concentrically around the axis of rotation 1 , which makes it very easy to integrate the damping device 10 . As Fig. 3 shows, the damping device 10 is arranged between a Z-shaped center ring and the pulley 24. The Z-shaped center ring supports the pulley 24 by a slide bearing and forms the inertial mass of the damping system. The damping device according to the invention thus acts in the case of the torsionally flexible coupling shown in FIG. 3 in addition to an elastomeric damping body 21 . Large torsional vibration amplitudes occurring in the resonance range of the drive system can thereby be effectively damped. The torque transmission is not impaired in its function by the failure of the damping device connected in parallel.

Claims (18)

1. Damping device for a torsionally flexible coupling, comprising an outer ring ( 3 ) and an inner ring ( 2 ) which enclose each other at a radial distance to form an annular gap ( 13 ) and which are rotatably mounted relative to one another about an axis of rotation ( 1 ) , at least one pressure body ( 4 ) fixed in the annular gap on one of the rings with a stop surface ( 14 ) which projects continuously in the circumferential direction, at least two working chambers ( 5 , 5 ') which are delimited by elastic, deformable walls ( 7 ) and are filled with a damping medium , which are attached to the other of the rings, which, viewed in the circumferential direction, each extend in the annular gap on both sides of the pressing body ( 4 ) and which are in operative connection with an associated compensation chamber ( 6 , 6 ') through at least one overflow opening ( 9 ), a spring fixed in the annular gap on the other of the rings and arranged between the pressing body and the working chambers body ( 11 ), which can be pressed against the wall surface of a working chamber ( 5 , 5 ') in such a way that the damping medium is deformed by the wall ( 7 ) when the rings ( 2 , 3 ) are rotated by the stop surface ( 14 ) Overflow opening ( 9 ) flows into the associated compensation chamber ( 6 , 6 '). 2. Damping device according to claims 1, characterized in that the spring body ( 11 ), seen in the circumferential direction, is kidney-shaped with thickened end pieces ( 12 ), has a concavely curved cam surface ( 16 ) lying to the pressing body, which, in each case in the direction of a working chamber ( 5 , 5 ')), is continuously formed in a cam flank ( 17 ) of the respective end piece ( 12 ) so that the relative rotation of the rings ( 2 , 3 ) with a continuously changing ratio in a contact pressure of one of the working chambers ( 5 , 5 ') is implemented. 3. Damping device according to claim 1 or 2, characterized in that the walls ( 7 ) of the working chambers ( 5 , 5 ') or compensation chambers ( 6 , 6 ') are formed by an annular hose ( 28 ). 4. Damping device according to claim 3, characterized in that each working chamber ( 5 , 5 ') and its associated compensation chamber ( 6 , 6 ') by at least one rigid overflow plate ( 8 , 8 ', 8 ") fixed in the annular hose ( 28 ) are separated which has at least one overflow channel ( 9 ). 5. Damping device according to one of the preceding claims, characterized in that in a non-rotating state of the damping device, each cam flank ( 17 ) with the stop surface ( 14 ) includes a circumferential distance ( 15 ). 6. Damping device according to one of the preceding claims, characterized in that in a non-rotating state of the damping device, each cam flank ( 17 ) touches the stop surface ( 14 ). 7. Damping device according to one of the preceding claims, characterized in that the pressing body ( 4 ) is designed as a cam ( 18 ). 8. Damping device according to one of the preceding claims, characterized in that the pressing body ( 4 ) is formed by a rolling body ( 19 ). 9. Damping device according to one of the preceding claims, characterized in that the working chamber ( 5 , 5 ') and / or the compensation chamber ( 6 , 6 ') is provided with a closable opening ( 22 ) for filling or venting. 10. Damping device according to one of the preceding claims, characterized in that the wall ( 7 ) of each working chamber ( 5 , 5 ') is designed with an elasticity such that the damping medium when the pressing body ( 4 ) is not pressed on due to the elastic regression of the wall ( 7 ) from the compensation chamber ( 6 , 6 ') through the overflow opening ( 9 ) in the working chamber ( 5 , 5 ') can be returned. 11. Damping device according to one of the preceding claims, characterized in that the wall ( 7 ) of the working chamber ( 5 , 5 ') or the compensation chamber ( 6 , 6 ') is formed at least in sections as a bellows. 12. Damping device according to one of the preceding claims, characterized in that the damping medium is a gas. 13. Damping device according to one of claims 1 to 11, characterized characterized in that the damping medium is a hydraulic Liquid is.   14. Damping device according to one of the preceding claims 1 to 11, characterized in that the damping medium Lubricant, preferably a hydraulic oil. 15. Damping device according to claim 14, characterized in that the lubricant contains fine grain solids. 16. Torsionally flexible coupling in which at least one damping device ( 10 ) is provided according to one of the preceding claims. 17. Torsionally flexible coupling according to claim 16, characterized in that the at least one damping device ( 10 ) is arranged in a functional parallel connection to a spring body ( 21 ). 18. Torsionally flexible coupling according to claim 17, characterized in that the spring body ( 21 ) is formed by an elastomer.