DE102015215251A1 - coupling device - Google Patents

Abstract

The invention relates to a coupling device which can be mounted rotatably about an axis of rotation, wherein the coupling device comprises a friction pack, a disk carrier and a spring device, wherein the disk carrier has a toothing, wherein the friction pack has at least a first friction partner and a further first friction partner, wherein the first and the other first friction partners are torque-locking connected to the plate carrier, wherein the spring means is arranged axially between the first friction partner and the other first friction partner, wherein the spring means engages at least partially in the toothing of the disc carrier.

Description

The invention relates to a coupling device according to claim 1.

From the EP 1 630 447 B2 is a wet double clutch known. The dual clutch has a friction pack with a large number of steel disks and a large number of friction disks. Between the steel blades, a spring device is arranged.

It is an object of the invention to provide an improved coupling device.

This object is achieved by means of a coupling device according to claim 1. Advantageous embodiments are given in the dependent claims.

According to the invention, it has been recognized that an improved coupling device can be provided in that the coupling device can be mounted rotatably about an axis of rotation, wherein the coupling device comprises a friction pack, a plate carrier and a spring device. The plate carrier comprises a toothing. The friction pack has at least one first friction partner and a further first friction partner, the first and the further first friction partners being connected in a torque-locking manner to the disk carrier. Axially between the first friction partner and the other first friction partner, the spring device is arranged. The spring device engages at least partially in the toothing of the disk carrier.

This embodiment has the advantage that the coupling device can be made particularly compact in the radial direction and at the same time a ventilation of the first friction partners can be reliably ensured when the coupling device is open. As a result, reliable cooling, in particular when designing the coupling device as a wet coupling device, can be ensured. Also, a wear in the friction package is minimized.

In a further embodiment, the spring device has at least one spring element with a spring tongue. The spring tongue extends at least in sections in the radial direction. The spring tongue engages with a free end in the toothing. Thereby, the space that is available through the teeth, are used in addition by the engagement of the spring tongue in the toothing for the spring element for releasing the friction partners in the friction package.

In a further embodiment, the spring element is designed as a plate spring. This embodiment ensures that particularly high forces for ventilating the friction partners in the friction package can be provided.

In a further embodiment, the spring element has a closed region. The spring tongue is connected with a fixed end to the closed area. The closed region lies radially on a side facing away from the spring tongue on the first friction partner. The spring tongue abuts against the other first friction partner at a free end. This avoids tilting of the friction partners in the first friction pack and thus undesired possible frictional contact between the friction partners.

In a further embodiment, the toothing has a tooth gap. The spring tongue is at least partially narrower in the circumferential direction than the interdental space. As a result, a reliable passage of cooling fluid into the friction pack, or out of the friction pack, is ensured via the interdental space.

In a further embodiment, the plate carrier has a passage opening arranged in the toothing. The passage opening opens at a tooth base of the toothing. The spring tongue is, preferably in the circumferential direction, offset from the passage opening. As a result, a particularly high flow of cooling fluid through the passage opening for guiding the friction pack can be ensured.

In a further embodiment, a second friction partner of the friction pack is arranged axially between the first friction partner and the further first friction partner. The spring device is arranged radially on the outside and / or radially inside of the second friction partner. Additionally or alternatively, the spring device is arranged axially overlapping to the second friction partner.

In a further embodiment, the first friction partner and the further first friction partner is designed as a coating-free friction disk.

In a further embodiment, the toothing is designed as external toothing or as internal toothing.

In a further embodiment, the coupling device is designed as a double clutch, in particular as a wet-running double clutch.

The invention will be explained in more detail with reference to figures. Showing:

1 a semi-longitudinal section through a coupling device;

2 a section of the in 1 shown half longitudinal section of in 1 shown coupling device; and

3 a section of a sectional view along an in 2 shown section plane AA through in the 1 and 2 shown coupling device.

1 shows a semi-longitudinal section through a coupling device 10 ,

The coupling device 10 is rotatable about an axis of rotation 15 stored. The coupling device 10 has an entry page 20 and an exit side 25 on. The entrance page 20 is configured to be torque-connected to an output side of a reciprocating engine. The exit side 25 the coupling device 10 includes a first hub 30 and a second hub 35 , The first hub 30 provides a torque-locked connection to a first transmission input shaft 40 (shown in dashed lines) a transmission device available. The second hub 35 provides a torque-locked connection to a second transmission input shaft 45 (dashed lines) of the transmission device available. Furthermore, the coupling device comprises 10 a rotor 50 which is formed with a control device of the coupling device 10 to be connected. The coupling device 10 includes a first friction package 55 and a second friction package 60 , In the embodiment, the first friction pack is an example 55 radially outside to the second Reibpaket 60 arranged. The two friction packages 55 . 60 each have first and second friction partners 65 . 66 . 67 . 70 on.

The coupling device 10 has a driver unit 80 on. The driver unit 80 includes a first plate carrier 85 , a pressure ring 86 and a driver part 90 , The pressure ring 86 is axially adjacent to the first plate carrier 85 arranged. The driver part 90 is axially adjacent to the thrust ring 86 on one to the first friction package 55 migrated side arranged. The driver part 90 is formed like a disk and is radially inside with the input side 20 the coupling device 10 torque-connected, for example, with a first connection 91 , in particular a welded joint. Radially outside is the pressure ring 86 with the first plate carrier 85 connected torque-locking.

The first plate carrier 85 is pot-shaped and has an axially extending portion 92 and a radially extending portion 93 on. The radially extending section 93 is radially inward via a second connection 95 , which is formed in the embodiment as a welded joint, with the rotor 50 connected torque-locking. Essentially, the driver unit limits 80 an interior 100 in which the two friction packages 55 . 60 are arranged.

In the interior 100 the coupling device 10 are also a first actuator 105 and a second actuator 110 intended. The first actuating device 105 has a first pressure chamber 115 and the second actuator 110 a second pressure chamber 120 on. The two pressure chambers 115 . 120 are not shown lines in the rotor 50 are arranged, hydraulically connected to the control unit.

The first actuating device 105 has a first actuating element 125 on. The first actuator 125 extends radially inward from the first pressure chamber 115 radially outwards until the first friction pack 55 , The second actuator 110 includes a second actuator 130 extending radially from the radially inner side disposed second pressure chamber 120 to substantially radially at the height of the second Reibpakets 60 extends.

The coupling device 10 further comprises a second plate carrier 135 , a third plate carrier 140 and a fourth plate carrier 145 , The second, third and fourth plate carrier 135 . 140 . 145 are pot-shaped and each have a radially extending portion and each having an axially extending portion. Radial inside the radially extending portion is the second plate carrier 135 torque-locking with the second hub 35 connected. The second plate carrier 135 is designed as an inner disk carrier and has a first toothing formed first outer toothing 150 on. The first plate carrier 85 and the second disc carrier 135 form a first annular gap in which the first Reibpaket 55 is arranged.

Here are the first friction partners 65 . 66 . 67 designed as a non-wearing friction plates, while the second friction partners 70 are formed as lining lamellae. Of course, other embodiments are conceivable. In this case, the first friction partner 65 a trained as a second toothing first internal toothing 79 and another first friction partner 66 . 67 a trained as a further second toothing first internal toothing 79 and the second friction partner 70 a second external toothing 75 on.

In the first external toothing 150 of the second disc carrier 135 grips the first internal toothing 79 the first friction partner 65 . 66 . 67 of the first friction package 55 one, so the first friction partners 65 . 66 . 67 torque-locking with the second plate carrier 135 are connected.

The first plate carrier 85 has a second internal toothing 155 on. The second internal toothing 155 and the second outer toothing 75 the second friction partner 70 are formed corresponding to each other, wherein the second outer toothing 75 in the second internal toothing 155 of the first disk carrier 85 engages, so the second friction partners 70 of the first friction package 55 torque-locking with the first plate carrier 85 are connected.

Will over the rotor 50 a pressurized fluid in the first pressure chamber 115 initiated, so is the first actuator 125 in the axial direction in the direction of the first Reibpakets 55 postponed. One is over the first pressure chamber 115 provided actuating force F via the first actuating element 125 in the first rubbing package 55 initiated.

The driver part 90 is axially on an opposite side of the first Reibpakets 55 arranged. The pressure ring 86 serves to provide a corresponding to the actuating force F counterforce F _G. As a result, by means of the first actuating element 125 the friction partners 65 . 66 . 67 . 70 of the first friction package 55 axially pressed against each other, so that the friction partners 65 . 66 . 67 . 70 build up a frictional connection and the first plate carrier 85 torque-locking with the second plate carrier 135 connect. In this way, a torque M from the input side 20 over the driver part 90 , the first plate carrier 85 and the first friction package 55 in the second plate carrier 135 and over this into the second hub 35 be initiated.

The third plate carrier 140 and the fourth plate carrier 145 form a second annular gap in which the second Reibpaket 60 is arranged. Analogous to the configuration of the first disk carrier 85 is the third plate carrier 140 trained and provides a torque-locking connection with the second Reibpartnern 70 of the second friction package 60 ready. Furthermore, the third plate carrier 140 torque-locked radially on the inside with the rotor 50 connected. The first friction partners 65 . 66 . 67 of the second friction package 60 are torque-locking with the fourth plate carrier 145 analogous to the connection of the first friction partner 65 . 66 . 67 with the second plate carrier 135 connected. The fourth plate carrier 145 is radially inward torque-locking with the first hub 30 connected.

Will the pressurized fluid over the rotor 50 in the second pressure chamber 120 initiated, then the second actuating element 130 axially displaced and pressed the second Reibpaket 60 so that a torque lock between the third plate carrier 140 and fourth plate carrier 145 provided. In this case, the torque M is from the input side 20 over the driver part 90 to the first plate carrier 85 and from this to the rotor 50 transfer. From the rotor 50 the torque M continues over the third plate carrier 140 and the second friction package 60 in the fourth plate carrier 145 and from there to the first hub 30 forwarded.

2 shows a section of the in 1 shown half longitudinal section of in 1 shown coupling device 10 ,

The coupling device 10 preferably comprises for the first friction package 55 , additionally or alternatively also for the second friction package 60 , a spring device 160 , The spring device 160 includes by way of example a first spring element 165 and a second spring element 170 , The first spring element 165 is axial between the first friction partner 65 and the next, the first friction partner 65 arranged further first friction partner 66 arranged. Furthermore, axially between the first friction partner 65 and the other first friction partner 66 . 67 the second friction partner 70 arranged. Radially inside to the second friction partner 70 is the spring element 165 . 170 arranged. The second spring element 170 is between the other first friction partner 66 and on one to the first friction partner 65 axially opposite side further first friction partner 67 arranged. Preferably, the spring element 165 . 170 radially inside to the first friction partner 65 arranged. In this case, in the embodiment, the spring element 165 . 170 axially overlapping overlapping to the second friction partner 70 arranged. It is understood by an axial overlap that when the second friction partner 70 and the spring element 165 . 170 in a plane in which the axis of rotation 15 runs, be projected, these overlap at least in sections.

The spring element 165 . 170 is exemplified in the embodiment as a plate spring. Of course, the spring element 165 . 170 also be designed differently. Also, the first spring element 165 as a plate spring and for example the second spring element 170 differently to the first spring element 165 , For example, as a compression spring, coil spring, corrugated ring, be formed.

The spring element 165 . 170 engages in the first external toothing 150 one. This requires the spring element 165 . 170 in the radial direction, particularly little installation space between a radially outer end, in the embodiment by way of example a tooth tip diameter of the first outer toothing 150 , and an inner peripheral surface 171 of the second friction partner 70 , In particular, thereby the frictional contact in its surface between the first friction partner 65 . 66 . 67 and the second friction partner 70 be particularly large.

The first spring element 165 has radially inwardly on a first further friction partner 65 facing first end face 175 a first touch contact 185 with a tooth 180 the first internal toothing 79 on. The second spring element 170 is mirror-symmetrical to the first spring element 165 related to a plane of symmetry 192 that is perpendicular to the axis of rotation 15 and by the first other friction partner 66 extends. In this case, the second spring element 170 radially inside a second contact contact 190 on an axial to the first end face 175 the first additional friction partner 66 opposite second end face 195 on the tooth 180 the first internal toothing 79 on. The first contact 185 is radially overlapping to the second contact 190 arranged. It is understood by a radial overlap that when the first touch contact 185 and the second touch contact 190 in a plane of rotation perpendicular to the axis of rotation 15 is arranged, projected, these overlap at least partially in the plane of rotation. This causes a tilting of the other first friction partner 66 avoided.

Due to the design of the spring element 165 . 170 by way of example as a plate spring, the spring element preferably extends 165 . 170 in the half-longitudinal section oblique to the axis of rotation 15 , Also, other orientations of the spring element 165 . 170 conceivable.

Radially on the outside, the first spring element 165 a third touch contact 196 with the first friction partner 165 in a carrier section 200 of the first friction partner 65 on. The carrier section 200 is radially outward to the first internal toothing 79 arranged. The second spring element 170 has a fourth touch contact 205 on. The fourth contact is radially overlapping the third contact 196 arranged.

By the opposite orientation of the spring elements 165 . 170 is a tilting of the between the spring elements 165 . 170 arranged first friction partner 65 . 66 . 67 reliably avoided. It also ensures that when the coupling device is open 10 that is, when substantially no actuating force F is provided, the spring elements 165 . 170 the first friction partners 65 . 66 . 67 can press apart axially so that the first friction partners 65 . 66 . 67 no frictional contact with the second friction partner 70 exhibit. As a result, on the one hand, a reliable guidance of the coolant through the first friction pack 55 guaranteed. It also ensures that a friction lining 209 of the second friction partner 70 by an undesired frictional contact with the first friction partner 65 . 66 . 67 when the clutch device is open 10 not worn out.

3 shows a section of a cross section through the in 2 shown coupling device 10 , This applies to the first spring element described below 165 also for the second spring element 170 , The first spring element 165 preferably has a plurality of circumferentially offset staggered spring tongues 210 . 215 on. The spring tongues 210 . 215 are arranged circumferentially spaced from each other. In this case, the spring tongue 210 . 215 a first spring tongue flank 220 and a second spring tongue flank 225 on. The spring tongue flanks 220 . 225 are arranged offset in the circumferential direction.

The spring tongues 210 . 215 are with a firm ending 250 with a closed area 255 in the embodiment, for example, annular, of the first spring element 165 connected. The closed area 255 engages radially outside the first outer toothing 150 , This is a self-rigid first spring element 165 provided. Radial on the outside shows the closed area 255 the fourth touch contact 205 with the likewise closed trained support section 200 of the first friction partner 65 on.

In the embodiment, the spring tongue extends 210 . 215 radially from the closed area 255 inside. Also, the spring tongue 210 . 215 radially outside to the closed area 255 be arranged and extend radially outward.

The first external toothing 150 has a plurality of circumferentially spaced apart teeth 230 on. The teeth 230 each have a first tooth flank 235 and a second tooth flank 240 on. An interdental space 245 the first external toothing 150 is doing in the circumferential direction by the tooth flanks 235 . 240 limited. In this case, the first tooth flank is an example 235 parallel to the first spring tongue flank 220 arranged. The second spring tongue flank 225 is parallel to the second tooth flank 240 arranged. The spring tongue 210 . 215 grabs a free end 226 between the tooth flanks 235 . 240 in the interdental space 245 one.

In the embodiment, the spring tongue 210 . 215 narrower in the circumferential direction than a tooth space 245 between the teeth 230 the first external toothing 150 , This will ensure a safe compression of the spring tongue 210 . 215 ensured. In addition, a channel 245 between the tooth flanks 235 . 240 and the spring tongue flanks 220 . 225 for guiding coolant between the first spring element 165 and the second disc carrier 135 be ensured. This allows a reliable cooling of the friction lining 209 of the second friction partner 70 be ensured.

In the embodiment, the second plate carrier exemplifies 135 one in the first outer toothing 150 arranged passage opening 260 on. The passage opening 260 is in a tooth base 265 the first external toothing 150 for example, centrally between two circumferentially adjacent teeth 180 arranged. Also, the arrangement and the provision of the passage opening 260 be formed differently. In order to ensure a reliable discharge of radially inward to radially outward flowing cooling liquid is in the embodiment radially outside to the passage opening 260 the spring tongue 210 . 215 arranged offset, so that a reliable cooling of the friction lining 209 of the second friction partner 70 is ensured. Also, the spring tongue 210 . 215 a circumferentially overlapping the passage opening 260 arranged recess 270 have (dashed lines shown) to a reliable passage of the cooling liquid through the passage opening 260 sure.

In the embodiment, the spring device 160 exemplary of the first friction package 55 shown. Of course, it is also conceivable that the spring device 160 on the second friction package 60 is provided.

It is also conceivable that the coupling of the first friction partners 65 . 66 . 67 and the second friction partner 70 with the plate carriers 85 . 135 . 140 . 145 different than in the 1 to 3 is described. For example, it is also conceivable that the first friction partners 65 . 66 . 67 radially outside with the first or third disc carrier 85 . 140 and the second friction partner 70 with the second and / or fourth plate carrier 135 . 145 is coupled. In this case, for example, then the spring device 160 radially outside to the second friction partner 70 arranged.

It is also conceivable that the just described coupling of the first friction partner 65 . 66 . 67 radially outside with the plate carrier 85 . 135 . 140 . 145 only on the second friction package 60 and those in the 1 to 3 described coupling of the first friction partner 65 . 66 . 67 with the second plate carrier 135 only in the first rubbing package 55 is provided. Also, different couplings between the first Reibpartnern 65 . 66 . 67 and the plate carriers 85 . 135 . 140 . 145 and the second friction partner 70 with the other plate carriers 85 . 135 . 140 . 145 conceivable.

The in the 1 to 3 described coupling device 10 has the advantage that a reliable ventilation of the first friction partner 65 . 66 . 67 in the rubbing package 55 . 60 is ensured. Also, a reliable flow of the cooling liquid in the Reibpaket 55 . 60 on the spring device 160 over ensured.

Furthermore, a reliable torque exchange between the spring device 160 and the second disc carrier 135 ensured, so that wear of the spring device 160 in contact with the friction partner 65 . 66 . 67 . 70 , in particular by speed differences, is avoided. It should be noted that in the 1 to 3 Of course, the features described can also be combined differently or individual features can be omitted.

The in the 1 described coupling device 10 is formed in the embodiment as a double clutch. Here, the double clutch is designed as a wet-running double clutch, so that a cooling liquid is provided to the friction packs 55 . 60 to cool. Of course, it is also conceivable that the coupling device 10 as a simple clutch - so with just a friction package 55 . 60 - is trained. Also, other embodiments of the coupling device 10 conceivable.

LIST OF REFERENCE NUMBERS

10

 coupling device

15

 axis of rotation

20

 input side

25

 output side

30

 first hub

35

 second hub

40

 first transmission input shaft

45

 second transmission input shaft

50

 rotor

55

 first friction package

60

 second friction package

65

 first friction partner

66

 another first friction partner

67

 another first friction partner

70

 second friction partner

75

 second external toothing

79

 first internal toothing

80

 Driver unit

85

 first plate carrier (outer plate carrier)

86

 pressure ring

90

 driver part

91

 first connection

92

 axial section

93

 radial section

95

 second connection

100

 inner space

105

 first actuating device

110

 second actuating device

115

 first pressure chamber

120

 second pressure chamber

125

 first actuating element

130

 second actuator

135

 second plate carrier (inner plate carrier)

140

 third plate carrier (outer plate carrier)

145

 fourth plate carrier (inner plate carrier)

150

 first external toothing

155

 second internal toothing

160

 spring means

165

 first spring element

170

 second spring element

171

 inner peripheral surface

175

 first end face of the first further friction partner

180

 Tooth of the first internal toothing

185

 first contact

190

 second contact

192

 plane of symmetry

195

 second end face

196

 third touch contact

200

 support section

205

 fourth touch contact

209

 friction lining

210

 first spring tongue

215

 second spring tongue

220

 first spring tongue flank

225

 second spring tongue flank

226

free end

230

 Tooth of the first external toothing

235

 first tooth flank

240

 second tooth flank

245

 Interdental

246

 channel

250

 solid end

255

closed area of the spring element

260

 Through opening

265

 tooth root

270

 recess

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 1630447 B2 [0002]

Claims (10)

Coupling device ( 10 ) which is rotatable about an axis of rotation ( 15 ) is storable, - having a friction package ( 55 . 60 ), a plate carrier ( 85 . 135 . 140 . 145 ) and a spring device ( 160 ), - wherein the plate carrier ( 85 . 135 . 140 . 145 ) a gearing ( 150 ), wherein the friction package ( 55 . 60 ) at least one first friction partner ( 65 ) and another first friction partner ( 66 . 67 ), wherein the first and the further first friction partners ( 65 . 66 . 67 ) torque-locking with the plate carrier ( 85 . 135 . 140 . 145 ), wherein axially between the first friction partner ( 65 ) and the other first friction partner ( 66 . 67 ) the spring device ( 160 ) is arranged, - wherein the spring device ( 160 ) at least in sections into the toothing ( 150 ) of the disk carrier ( 85 . 135 . 140 . 145 ) intervenes. Coupling device ( 10 ) according to claim 1, - wherein the spring device ( 160 ) at least one spring element ( 165 . 170 ) with at least one spring tongue ( 210 . 215 ), wherein the spring tongue ( 210 . 215 ) extends in sections in the radial direction, - wherein the spring tongue ( 210 . 215 ) with a free end ( 226 ) into the gearing ( 150 ) intervenes. Coupling device ( 10 ) according to claim 2, wherein the spring element ( 165 . 170 ) is designed as a plate spring. Coupling device ( 10 ) according to claim 2 or 3, - wherein the spring element ( 165 . 170 ) a closed area ( 255 ), wherein the spring tongue ( 210 . 215 ) with a fixed end ( 250 ) with the closed area ( 255 ), the closed area ( 255 ) radially on a spring tongue ( 210 . 215 ) facing away from the first friction partner ( 65 ), - wherein the spring tongue ( 210 . 215 ) at the free end ( 226 ) at the further first friction partner ( 66 . 67 ) is present. Coupling device ( 10 ) according to one of claims 2 to 4, - wherein the toothing ( 150 ) a tooth space ( 245 ), - wherein the spring tongue ( 210 . 215 ) is formed at least partially narrower in the circumferential direction than the interdental space ( 245 ). Coupling device ( 10 ) according to one of claims 2 to 5, - wherein the plate carrier ( 85 . 135 . 140 . 145 ) one in the toothing ( 150 ) arranged passage opening ( 260 ), - wherein the passage opening ( 260 ) on a tooth base ( 265 ) of the gearing ( 150 ), - the spring tongue ( 210 . 215 ), preferably in the circumferential direction, offset from the passage opening ( 260 ) is arranged. Coupling device ( 10 ) according to one of claims 1 to 5, - wherein axially between the first friction partner ( 65 ) and the other first friction partner ( 66 . 67 ) a second friction partner ( 70 ) of the friction package ( 55 . 60 ) is arranged, - wherein the spring device ( 160 ) radially on the outside and / or inside of the second friction partner ( 70 ) is arranged, - and / or - wherein the spring device ( 160 ) axially overlapping to the second friction partner ( 70 ) is arranged. Coupling device ( 10 ) according to one of claims 1 to 7, wherein the first friction partner ( 65 ) and the other first friction partner ( 66 . 67 ) are designed as a non-wearing friction plate. Coupling device ( 10 ) according to one of claims 1 to 8, - wherein the toothing as external toothing ( 150 ) or is designed as internal toothing. Coupling device ( 10 ) according to one of claims 1 to 9, wherein the coupling device ( 10 ) is designed as a double clutch, in particular as a wet-running double clutch.

Images