DE202008000815U1 - Torsionally flexible shaft coupling - Google Patents

Abstract

Torsionally flexible shaft coupling (10) for in particular boat drives with a drive-side coupling flange (20, 26) and a driven-side hub (12), which are connected to each other in a force-transmitting manner by means of two torsionally flexible coupling elements, characterized in that a first coupling element with progressive torsional rigidity (1) and a second coupling element with linear torsional stiffness (2) are arranged in a single stage in series one behind the other.

Description

The The invention relates to a torsionally flexible shaft coupling for in particular boat drives with a drive-side coupling flange and a driven-side hub, which by means of two torsionally elastic Coupling elements connected to each other in a force-transmitting manner are.

At torsionally flexible shaft couplings for maritime use, especially for boat drives, are very specific Requirements made. Especially when concerns a very much low torque - synonymous with boat drives with very low speeds - should the shaft coupling used be extremely soft. With increasing torque - at Boat drives synonymous with increasing speed - is a moderately increased torsional rigidity acceptable.

Provided the torsional elasticity of the coupling the applied torque not sufficiently considered, there is a risk of so-called Zähneratterns in the transmission. It is Sounds caused by the lifting of the tooth flanks from each other arise when the change torques larger are as the load torques. This problem exists in particular during engine idling and during partial load operation in transition between idle and workspace. Apart from the comfort reduction by the aforementioned noise means lifting the Tooth flanks of the gear wheels from each other a considerable Transmission load with consequent increased wear.

Of the Use of known single-stage couplings with a linear coupling element was not effective, because coupling elements with linear torsional stiffness especially at low torques no sufficient elasticity guarantee. The use of coupling elements with progressive Torsional stiffness ensured at low torques an acceptable operation, at high torques are such Coupling elements to torsionally stiff if necessary.

As a result, two- and three-stage clutches have been used in marine propulsion systems so far. An example of a two-stage clutch is DE 43 09 745 A1 the applicant, in which a first elastic coupling stage in the manner of a rubber roller clutch with clutch bodies mounted between the hub and an outer polygon has been preceded by a dog clutch. The rubber roller clutch ensures a high torsional elasticity in partial load operation, but is not sufficiently dimensioned for a power transmission in full load operation. Upon reaching a certain torque, therefore, engages the second, designed as a dog clutch coupling stage with higher torsional rigidity.

As an example of a three-stage clutch DE 44 03 477 C1 the Applicant listed, which serves as the first coupling stage from the aforementioned publication already known roller clutch. This in turn is designed for partial load operation and extremely soft. Upon reaching a certain nominal torque engages a torsionally rigid jaw clutch, which is followed by a torsionally soft third coupling stage.

With So far, both types of clutch have been able to cope with teeth be countered. With increasing efficiency of the Boat propulsion systems, however, both limits their coupling concepts. Problematic is basically the transitional area in which the first coupling stage reaches its power limit and the each next coupling stage with the power consumption starts. Also, it has been found that there are application areas where the second stage of the two-stage clutch at high Torque would have to be torsionally elastic.

It It should be noted that the classification terms "first, second, third" based on coupling stages or coupling elements in principle merely serve the conceptual distinction and not necessarily the serial order in terms of power flow within the featured Define shaft couplings.

task the invention is to provide a torsionally flexible shaft coupling, which over the entire torque or speed range in particular a boat drive the lowest possible Provides torsional elasticity.

Solved The task of a torsionally flexible shaft coupling with the Features of claim 1, in particular the characterizing features, after which a first coupling element with progressive torsional rigidity and a second coupling element with linear torsional stiffness in one stage arranged in series one behind the other.

to Solution to the problem, the invention of the hitherto taken because of the coupling construction. Instead of obvious finer subdivision into partial load ranges and the Construction of a multi-stage coupling, each with a coupling member for the respective partial load range, the problematic transition areas When a handle of the respective coupling stage avoided by a single-stage coupling element is created.

To turn off at low torques To ensure a sufficiently high torsional elasticity, a progressive coupling element is used whose high torsional stiffness is greatly mitigated at high torques by the combination with a linear coupling element. Due to the series connection of both coupling elements, the resulting torsional rigidity of the combination of both coupling elements is always less than the torsional rigidity of each individual coupling element. This ensures over the entire speed or torque curve an extremely high torsional elasticity, so that the lifting of the tooth flanks of the gear wheels is reliably avoided even in the critical part load range. In operation, both coupling elements contribute to the overall torsional elasticity. The low torsional stiffness at high torque results in very low alternating torques in the clutch and in the transmission. This results in a very quiet running and a long service life of the drive train.

by virtue of the series connection of the progressive and linear coupling element Both coupling elements are each for the full rated torque designed the drive. Due to its characteristic curve is suitable itself as a progressive coupling element, in particular a roller clutch.

moreover can the flow of force axially or radially through the linear coupling element be guided.

Around a compact as possible in the axial direction coupling To create, it is provided that the progressive coupling element at least partially disposed within the linear coupling element is or that the linear coupling element within the progressive coupling element is arranged. An axial series connection of the two coupling elements is also possible.

at A preferred embodiment provides that the central hub is opened radially outward, circumferentially distributed arranged first hollows and from surrounded by an annular body which opens radially inwardly, arranged circumferentially distributed and corresponding to the first troughs forms second wells, wherein two corresponding with each other Mulden a room for one rubber-elastic reel body form the roller clutch, in particular when the ring body a radially outwardly directed collar with axial Vulkanisationsfläche forms, the axially adjacent to the Drive side coupling flange with also a Vulkanisationsfläche is assigned and when collar and coupling flange by means of a annular, rubber-elastic coupling body connected to each other.

So are the progressive coupling element in the form of a roller clutch and the linear coupling element in the form of a rubber-elastic Ring body nested in each other, what a represents concrete embodiment of an axially compact coupling. In the present case, the power flow is axially by the linear Guided coupling element.

alternative the ring body can be a radially outwardly facing Vulcanization surface having a radially inward assigned facing Vulkanisationsfläche the coupling flange is, wherein annular body and coupling flange by means of a annular, rubber-elastic coupling body connected to each other. Instead of vulcanization to the outer Ring body can this form-fitting by means of a Gearing with or without preload with the annular be connected to rubber-elastic body. So lets a torsionally flexible shaft coupling with radial force flow realize.

Further Advantages of the invention and a better understanding revealed yourself from the following description of the drawing. Show it:

1 a view of the output side of a torsionally flexible coupling,

2 a view of the drive side of the torsionally flexible coupling according to 1 .

3 a section of the torsionally flexible coupling according to section line IV-IV in 2 with axial force flow through the coupling element with linear torsional rigidity,

4 a sectional view of an alternative embodiment of the torsionally elastic shaft coupling with radial force flow through the coupling element with linear torsional stiffness in analogy to section line IV-IV in 2 .

5 a diagram with characteristics of different types of couplings.

In the figures, a torsionally flexible shaft coupling for boat drives with the reference number 10 designated.

The torsionally flexible shaft coupling 10 comprises a central, substantially disk-shaped body 11 who is a central hub 12 forms for an output shaft, not shown. The radial outer surface of the body 11 Forms outside circumferentially distributed and outwardly open first wells 13 out, as in particular in the 2 is clearly recognizable.

The central body 11 is radially spaced from an annular body 14 surrounded, in turn, to the body 11 open, circumferentially distributed and with the first hollows 13 corresponding second wells 15 formed. This is very good from the 1 seen.

Corresponding first and second wells 13 . 15 together form a space for a rubber-elastic reel body 16 , The diameter of each elastic reel body 16 may be equal to, slightly smaller or slightly larger than the maximum distance between the inner surfaces 17 corresponding first and second wells 13 . 15 be.

The role of a classic roller clutch only serve the role of body 16 the transmission of a ring body to the central hub 12 applied torsional force. Without the presence of the reel body 16 within the means of the hollows 13 and 15 formed bearing shells would find no power transmission from the ring body 18 on the central body 11 instead of.

Out 1 and 2 is still recognizable that the respective wells 13 and 15 in the central body 11 and ring body 14 are formed asymmetrically in the circumferential direction. It is (the outer ring body 14 turns in the direction of arrow D relative to the body 11 ) made the arrangement so that the flatter edge of the respective trough 13 and 15 becomes effective, whereby the coupling in this direction of rotation, which corresponds to the direction of rotation of the motor, is softer than in the opposite direction of rotation, as can be readily imagined, when the roller body 16 from the surface areas of the respective trough which are steeper to the circumferential direction 13 and 15 is tangent.

In a first embodiment of the invention according to 3 carries the outer ring body 14 a substantially radially outwardly directed collar 18 with an axial to a coupling flange 20 pointing vulcanization surface 19 , The coupling flange 20 serves the drive-side connection of aggregates, in particular an engine flywheel, and has in addition to mounting holes 21 for bolt also has a vulcanization surface, which with 22 is designated. This is the vulcanization area 19 of the collar 18 facing, wherein the annular body 14 and the coupling flange 20 by means of an annular vulcanized, elastic coupling body 23 are connected together from an elastomer.

The above-described torsionally flexible shaft coupling 10 thus consists of two coupling elements. As a first coupling element is to consider the roller clutch, which has a progressive torsional rigidity. The advantage of this first coupling element can be seen in particular in the high torsional elasticity at low torques. The torsional vibrations originating from the drive are very well absorbed and dampened in particular by the roller clutch in the lower torque range.

In order to counteract the high coupling stiffness resulting from the progressive torsional elasticity characteristic of the roller clutch, which results in a low damping effect and thus generates high alternating torques, the second clutch element with a linear torsional elasticity characteristic is connected in series with the roller clutch. In the present embodiment, it is the annular coupling element 23 ,

4 shows the sectional view of an alternative design of the torsionally elastic shaft coupling according to the invention 10 , This is a coupling with radial force flow through the coupling element with linear torsional elasticity characteristic, said shaft coupling 10 in analogy to the section lines IV-IV in 2 is shown. Equivalent components have been provided here with identical reference numerals, with the preceding description of the drawing as far as possible to the embodiment of the invention according to 4 read.

As described above, the central coupling body forms 11 a hub for an output shaft, not shown, and carries as described above radially outwardly open troughs 13 , The one around the central body 11 arranged ring body 14 forms in analogy to the previously described embodiment radially inwardly open, the first wells 13 correspondingly associated second troughs 15 out, so here too a room for reel body 16 is created.

In contrast to the embodiment according to 3 has the ring body 14 but no axial, but a radially outwardly directed Vulkanisationsfläche 24 on, to which an annular, rubber-elastic coupling body 25 is vulcanized.

The annular coupling body 25 is from a coupling flange 26 with a radially inwardly facing Vulkanisationsfläche 27 surrounded and over this with the annular coupling body 25 rotatably connected. Alternatively, this connection can be made via the above-described positive connection. By means of axial bores 28 is the coupling flange 26 connectable with a drive-side flywheel.

As in the embodiment according to 3 is also in the second embodiment of the invention according to 4 the advantageous at low torques roller clutch with progressive torsional elasticity curve with an annular coupling body 25 connected with linear torsional elasticity characteristic in series. Unlike the embodiment according to 3 is the force flow in one embodiment according to 4 but a radial one.

It is essential to the invention that the proposed torsionally flexible shaft coupling is a single-stage coupling. Both coupling elements, so the roller clutch as well as the annular coupling body 25 respectively. 23 are each designed for the full nominal torque of the drive and act simultaneously in each state of the power transmission. In this case, in each operating state, each coupling element transmits in its entirety and simultaneously with the other coupling element the respective torque. Only the respective proportion of the resulting total torsional elasticity changes with increasing torque. However, in contrast to two-stage and multi-stage clutches, this happens dynamically and without a transitional area, in which, in stage clutches, the torsional elasticity of the first stage is almost exhausted, but that of the second stage is not yet sufficient.

5 shows three torsional elasticity curves of different couplings. With the reference number 1 is the characteristic of a progressive coupling, for example, the roller clutch used alone. As is apparent from the illustration, this is very well suited for damping torsional vibrations at low torques. It is very soft in these areas and therefore extremely elastic.

With the reference number 2 is the characteristic of a coupling with linear torsional elasticity - such as the coupling body 23 and 25 - designated. This becomes at a certain clutch load (in this example at about 55%) of the progressive characteristic 1 cut. Consequently, up to this point of intersection 4 the torsional elasticity of a linear coupling with characteristic 2 higher. For this reason, so far had been selected multi-stage clutches in which above a certain, relatively low torque from a first coupling stage to a second coupling stage was "switched".

With the reference number 3 is the characteristic of a torsionally flexible shaft coupling 10 shown, the progressive coupling element with the characteristic 1 and the linear coupling element with the characteristic curve 2 switched in series according to the invention in series. The resulting characteristic 3 is below the characteristic 2 of the linear coupling element used and approaches asymptotically to this characteristic. This is explained by the fact that both coupling elements act on every applied torque. Thus, it always results in the resultant of both torsional elasticities and this resulting torsional elasticity is always lower than the torsional elasticity of the individual clutches, even lower than that of the single clutch with the lowest torsional elasticity.

1

curve a coupling with progressive torsional rigidity

2

curve a coupling with linear torsional rigidity

3

Resulting characteristic of 1 and 2

4

intersection

10

Torsional flexible shaft coupling

11

central body v. 10

12

hub

13

first trough

14

ring body

15

second trough

16

rubber elastic roller body

17

inner surfaces

18

collar

19

axial vulcanization surface v. 18

20

coupling flange

21

Fixing holes v. 20

22

axial vulcanization surface v. 20

23

annular clutch body

24

radial vulcanization surface v. 14

25

annular clutch body

26

coupling flange

27

Vulcanization surface v. 26

28

Radial drilling v. 26

QUOTES INCLUDE IN THE DESCRIPTION

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

Cited patent literature

• - DE 4309745 A1 [0005]
• - DE 4403477 C1 [0006]

Claims (11)

Torsionally flexible shaft coupling ( 10 ) for in particular boat drives with a drive-side coupling flange ( 20 . 26 ) and a driven-side hub ( 12 ), which are connected to one another in a force-transmitting manner by means of two torsionally elastic coupling elements, characterized in that a first coupling element with progressive torsional rigidity ( 1 ) and a second coupling element with linear torsional rigidity ( 2 ) are arranged in a single stage in series one behind the other. Torsionally flexible shaft coupling according to claim 1, characterized characterized in that each of the coupling elements for the full rated torque of the drive is designed. Torsionally flexible shaft coupling according to claim 2, characterized characterized in that in each operating state each coupling element in full and simultaneously with the other coupling element transmits the respective torque. Torsionally elastic coupling element according to one of the preceding Claims, characterized in that the progressive Coupling element is designed as a roller clutch. Torsionally flexible shaft coupling according to one of the preceding Claims, characterized in that the power flow axially through the linear coupling element runs. Torsionally flexible shaft coupling according to one of the claims 1 to 3, characterized in that the power flow radially through the linear coupling element is running. Torsionally flexible coupling according to one of the preceding Claims, characterized in that the progressive Coupling element at least partially within the linear coupling element or that the linear coupling element at least partially within the progressive coupling element is arranged. Torsionally flexible shaft coupling according to one of claims 2 to 7, characterized in that the central hub ( 12 ) radially outwardly open, circumferentially distributed arranged first wells ( 13 ) and a ring body ( 14 ), the radially inwardly open, arranged circumferentially distributed and with the first wells ( 13 ) corresponding second wells ( 15 ), wherein two mutually corresponding troughs ( 13 . 15 ) a space for one rubber-elastic roller body ( 16 ) form the roller clutch. Torsionally flexible shaft coupling according to claim 8, characterized in that the annular body ( 14 ) a radially outwardly directed collar ( 18 ) with axial vulcanization surface ( 19 ), the axially adjacent the drive-side coupling flange ( 20 ) also having an axially directed vulcanization surface ( 22 ) and that collar ( 18 ) and coupling flange ( 20 ) by means of an annular, rubber-elastic coupling body ( 23 ) are interconnected. Torsionally flexible shaft coupling according to claim 7, characterized in that the annular body ( 14 ) a radially outwardly facing Vulkanisationsfläche ( 24 ) having a radially inwardly facing Vulkanisationsfläche ( 27 ) of the coupling flange ( 26 ), wherein coupling flange ( 26 ) and annular body ( 14 ) by means of an annular rubber-elastic coupling body ( 25 ) are interconnected. Torsionally flexible shaft coupling according to one of the claims 1 to 6, characterized in that the linear and the progressive Coupling element are arranged axially behind one another.