DE102018115185A1 - torsional vibration dampers - Google Patents

Abstract

Torsional vibration damper (100, 200, 300, 400), in particular dual-mass flywheel, the torsional vibration damper (100, 200, 300, 400) having an input part (102, 202, 302, 402), an output part (104, 204, 304, 404), a common axis of rotation (106, 206, 306, 406) around which the input part (102, 202, 302, 402) and the output part (104, 204, 304, 404) can be rotated together and by means of a bearing device (108, 208, 308 , 408) can be rotated relative to one another to a limited extent and can be tilted relative to one another, a spring-damper device acting in the circumferential direction between the input part (102, 202, 302, 402) and the output part (104, 204, 304, 404), and a radial one tilting play limiter (144, 246, 350, 444) spaced from the bearing device (108, 208, 308, 408), which, starting from a predetermined tilting angle, between the input part (102, 202, 302, 402) and the output part (104, 204, 304 , 404) is effective, characterized in that the tilt play limiter (144, 246, 350, 444) at least has an elastically deformable component formed separately from the input part (102, 202, 302, 402) and output part (104, 204, 304, 404).

Description

The invention relates to a torsional vibration damper, in particular dual-mass flywheel, the torsional vibration damper having an input part, an output part, a common axis of rotation about which the input part and the output part can be rotated together and rotated relative to one another to a limited extent and tilted relative to one another, one between the input part and the output part in the circumferential direction effective spring damper device, and a radially spaced from the bearing device tilt play limiter, which is effective from a predetermined tilt angle between the input part and the output part.

From the DE 10 2013 210 492 A1 a torsional vibration damper is known, in particular a dual mass flywheel, comprising an input part and an output part with a common axis of rotation about which the input part and the output part can be rotated together and rotated relative to one another to a limited extent, a spring-damper device which is effective between the input part and the output part, and a bearing device for mutually supporting the input part and the output part, the output part having a first radial support section which is axially extended towards the input part and which corresponds concentrically with a second radial support section of the input part.

From the DE 10 2017 117 853 A1 a torsional vibration damper is known, in particular a dual mass flywheel, the torsional vibration damper having an input part with a cover section and an output part with a common axis of rotation about which the input part and the output part can be rotated together and rotated relative to one another to a limited extent, a bearing device arranged between the input part and the output part and a spring-damper device effective between the input part and the output part, the bearing device being angularly movable and the input part having at least a first support section for support on the output part and the output part having at least a second support section for support on the input part, and the support sections corresponding to one another , are effective from a predetermined tilt angle between the input part and the output part and are spaced radially from the bearing device.

The invention is based on the object of structurally and / or functionally improving a torsional vibration damper mentioned at the outset.

The object is achieved with a torsional vibration damper with the features of claim 1.

The fact that the tilt play limiter has at least one elastically deformable component which is formed separately from the input part and the output part prevents a very hard impact between the input part and the output part. The tilt play limiter can dampen the impact. The tilt play limiter can cushion the striking.

The torsional vibration damper can be used for arrangement in a drive train of a vehicle. The drive train can have a drive machine. The prime mover can be an internal combustion engine. The internal combustion engine can have a crankshaft. The drive train can have a friction clutch device. The friction clutch device can have an electronic clutch management (EKM). The friction clutch device can have an electronic clutch (e-clutch). The drive train can have a hydrodynamic torque converter. The drive train can have a transmission. The drive train can have at least one drivable vehicle wheel. The drive train can have an auxiliary drive. The torsional vibration damper can be designed as a dual mass flywheel. The torsional vibration damper can be arranged between the drive machine and the hydrodynamic torque converter or the transmission.

The designations "input part" and "output part" refer to a line flow direction originating from a drive machine. Unless otherwise stated or the context does not indicate otherwise, the information “axial”, “radial” and “in the circumferential direction” relate to a direction of extension of the axis of rotation. "Axial" then corresponds to a direction of extension of the axis of rotation. "Radial" is then a direction perpendicular to the direction of extension of the axis of rotation and intersecting with the axis of rotation. "In the circumferential direction" then corresponds to a circular arc direction around the axis of rotation.

The spring-damper device effective in the circumferential direction can have at least one mechanical energy store. The at least one mechanical energy store can be supported on the one hand on the input part and on the other hand on the output part. The at least one mechanical energy store can be a coil spring. The at least one mechanical energy store can be a compression spring. The at least one mechanical energy store can be a Be bow spring. The friction device can have at least one friction disk.

The input part can have a flange section. The input part can have a cover section. The lid section can be annular. The cover section can have a radially outer edge. The cover section can have a radially inner edge. The flange section and the cover section can be firmly connected to one another. The flange section and the cover section can be integrally connected to one another, in particular welded. The flange section and the cover section can delimit a receiving space for at least one mechanical energy store. The receiving space can have a toroidal shape. The input part can have support sections for the at least one mechanical energy store projecting into the receiving space.

The output part can have a flange part. The flange part can be arranged axially between the flange section and the cover section. The flange part can have projections projecting radially outwards. The extensions can protrude into the recording room. The extensions can serve as support sections on the output part side for the at least one mechanical energy store. The output part can have a flywheel part. The flange part and the flywheel mass part can be firmly connected to one another. The flange part and the flywheel part can be non-positively and / or positively connected to one another, in particular riveted. The flywheel part can be arranged at least in sections axially next to the cover section.

The bearing device can serve for mutually rotatable mounting of the input part and the output part. In addition, the bearing device can enable a predetermined inclination of an axis of rotation of the input part and an axis of rotation of the output part. The bearing device can have at least one roller bearing. The bearing device can have at least one ball bearing. The bearing device can have at least one deep groove ball bearing.

The elastically deformable component of the tilt play limiter and a support surface can limit an active gap. The effective gap can decrease at least in sections with increasing axial and / or tilting load of the torsional vibration damper. From a predetermined tilt angle between the input part and the output part, the elastically deformable component of the tilt play limiter and a support surface can come into mutual contact at least in sections. The predetermined tilt angle can be approximately 0.2 ° to approximately 1 °, in particular approximately 0.3 ° to approximately 0.6 °. The elastically deformable component of the tilt play limiter and a support surface can be spaced as far as possible radially from the bearing device. If the predetermined tilt angle is exceeded, the elastically deformable component of the tilt play limiter can be elastically deformed by contacting the support surface.

The at least one elastically deformable component of the tilt play limiter and the at least one support surface can be arranged at least approximately in the radial direction in the region of the cover section. The elastically deformable component of the tilt play limiter and the support surface can be arranged in the radial direction at least approximately in the region of a radially outer edge of the cover section. The cover section can have a cover plate and a cover shoulder. The elastically deformable component of the tilt play limiter and the support surface can be arranged in the radial direction in a radially outer area of the cover plate.

The elastically deformable component of the tilt play limiter can have a contact area. The elastically deformable component can be assigned to the starting part. The contact area can contact a support surface of the input part when a predetermined tilt angle between the input part and the output part is reached. The elastically deformable component can be assigned to the input part. When a predetermined tilt angle between the input part and the output part is reached, the contact area can contact a support surface of the output part.

At least one support surface can be formed on the input part. The at least one support surface can be formed on the cover section of the input part. The at least one support surface can be formed in a radially outer region of a cover plate of the cover section. At least one support surface can be formed on the output part. The at least one support surface can be formed on the flywheel part of the output part. The at least one support surface can be formed in a radially outer area of the flywheel part.

The elastically deformable component can be an elastomer ring. The elastomer ring can be arranged in sections in a groove of a flywheel part of the output part. The elastically deformable component can be a plastic ring. The plastic ring can be arranged in sections in a groove of a flywheel part of the output part. A cover section of the input part can have an associated support surface.

The tilt play limiter can have several individual elements made of elastomer as elastically deformable components. The tilt play limiter can have several individual plastic elements as elastically deformable components. The individual elements can be arranged in openings in a flywheel part of the output part. A cover section of the input part can have a support surface. A cover section of the input part can have one or more support surfaces.

The tilt play limiter can have a plate spring as an elastically deformable component. The plate spring can be arranged in sections in a groove of a flywheel part of the output part. The plate spring can be arranged in sections in a groove of the input part. The plate spring can be clipped into the groove.

The plate spring can be held by an elastomer ring. The elastomer ring can be arranged in sections in a groove of the input part. The flywheel part of the output part can have a support surface. The plastic ring can be arranged in sections in a groove of the input part. The flywheel part of the output part can have a support surface. The elastomer ring can have several fastening means. The fastening means can be fingers for fixing the plate spring.

The plate spring can be held by a plastic ring. The plastic ring can be arranged in sections in a groove of the input part. The flywheel part of the output part can have a support surface. The plastic ring can be arranged in sections in a groove of the output part. The flywheel part of the input part can have a support surface. The plastic ring can have several fastening means. The fastening means can be fingers for fixing the plate spring.

The elastically deformable component can be a wire ring. The wire ring can be made of a spring wire. The elastically deformable component can be a wave-shaped wire ring. The shafts can extend in the axial direction. The elastically deformable component can be a meandering wire ring. The wire ring can be arranged in sections in a groove of a flywheel part of the output part. A cover section of the input part can have a support surface.

In summary and in other words, the invention thus results, inter alia, in an optimized tilt play limiter of a dual-mass flywheel, in particular in connection with a tilt-soft deep groove ball bearing. In particular, dual-mass flywheels for drive trains with an electronic clutch management (EKM) or an electronic clutch (e-clutch) require a tilt clearance limiter between the input part (primary part) and the output part (secondary part) in order to avoid overloading the special EKM bearing at high tilting moments. Compared to the tilting game limiters known from the prior art between the primary part and the secondary part of a torsional vibration damper / dual mass flywheel, which are designed as steel or cast parts with high rigidity, the rigidity of the tilting game limiter according to the invention is reduced. This leads to lower forces when striking. This solves the problem known from the prior art that hard stops on the tilt play limiter overcome the holding force of the bearing on its primary or secondary-side press seats and can pull the bearing away from the press seats as a result of many small microslip movements. According to the invention, the stiffness of the tilt play limiter is reduced by using materials with low stiffness (e.g. plastic or elastomer) or by deliberately incorporated spring elements (e.g. disc springs). In a preferred embodiment, the elasticity of the tilt play limiter is increased by at least one or more stop elements made of plastic or elastomer. The stop elements can be a circumferential ring or several individual elements distributed around the circumference. In a further preferred exemplary embodiment, a plate spring which is held axially on the secondary side (for example clipped in) is contacted and deformed during stop operations, so that the rigidity of the stop is reduced. In a further preferred exemplary embodiment, a plastic ring or elastomer ring (or individual elements attached to the circumference) attached on the primary side holds a plate spring-like disk via fingers on the plastic / elastomer, which is contacted and deformed when the secondary part tilts and thus reduces the rigidity of the stop.

With the torsional vibration damper according to the invention, a load on the bearing device is reduced. An impermissible load on the storage facility is prevented. A service life of the storage facility is increased. Operational safety is increased. A larger dimensioning of the storage facility can be omitted. A larger installation space is not necessary. An effort, such as an expense, is limited. An operationally required tilt angle between the input part and the output part is made possible. The risk of inventory withdrawal is reduced. If the bearing device is designed as a roller bearing, an inadmissible axial displacement of rolling elements is prevented.

Exemplary embodiments of the invention are described below with reference to figures described in more detail. Further features and advantages result from this description. Specific features of these embodiments may represent general features of the invention. Features of these exemplary embodiments associated with other features can also represent individual features of the invention.

• 1 ausschnittsweise ein Zweimassenschwungrad mit einem radial außenseitig einer Lagereinrichtung angeordneten Kippspielbegrenzer gemäß eines ersten Ausführungsbeispiels,
• 2 ausschnittsweise ein Zweimassenschwungrad mit einem radial außenseitig einer Lagereinrichtung angeordneten Kippspielbegrenzer gemäß eines zweiten Ausführungsbeispiels,
• 3 ausschnittsweise ein Zweimassenschwungrad mit einem radial außenseitig einer Lagereinrichtung angeordneten Kippspielbegrenzer gemäß eines dritten Ausführungsbeispiels, und
• 4 ausschnittsweise ein Zweimassenschwungrad mit einem radial außenseitig einer Lagereinrichtung angeordneten Kippspielbegrenzer gemäß eines vierten Ausführungsbeispiels.

They show schematically and as an example:

• 1 sections of a dual-mass flywheel with a tilt play limiter arranged radially on the outside of a bearing device according to a first exemplary embodiment,
• 2 sections of a dual-mass flywheel with a tilt play limiter arranged radially on the outside of a bearing device according to a second exemplary embodiment,
• 3 sections of a two-mass flywheel with a tilt play limiter arranged radially on the outside of a bearing device according to a third exemplary embodiment, and
• 4 Detail of a dual-mass flywheel with a tilt play limiter arranged radially on the outside of a bearing device according to a fourth exemplary embodiment.

1 shows one as a dual mass flywheel 100 trained torsional vibration damper according to a first embodiment. The dual mass flywheel 100 is used for arrangement in a drive train of a motor vehicle between an internal combustion engine and a friction clutch. The dual mass flywheel 100 is used to dampen rotational irregularities in the drive train. Such rotational irregularities can be excited in particular by the internal combustion engine.

The dual mass flywheel 100 has an input part 102 and an output part 104 with a common axis of rotation 106 on. The entrance part 102 and the output part 104 are about the axis of rotation 106 rotatable together and rotated to a limited extent relative to one another. For mutually rotatable mounting of the input part 102 and the output part 104 serves a single row deep groove ball bearing 108 , especially with increased osculation.

The deep groove ball bearing 108 has an inner ring 110 , an outer ring 112 and bullets like 114 , on. The inner ring 110 is at the entrance part 102 arranged. The outer ring 112 is at the output part 104 arranged. The balls 114 each have a spherical radius. The inner ring 110 points for the balls 114 a groove with a groove radius. The outer ring 112 points for the balls 114 a groove with a groove radius. The groove radii of the inner ring 110 and outer ring 112 are preferably each enlarged relative to the ball radius such that an axis of rotation of the inner ring 110 and an axis of rotation of the outer ring 112 are mutually angularly movable. The groove radii of the inner ring 110 and outer ring 112 are, for example, 110 percent of the sphere radius.

The entrance part 102 has a flange portion 116 and a lid section 118 on. The flange section 116 is disk-shaped and has a U-shaped cross section with a radially extending leg section 120 on. The leg section goes radially inside 120 in a circular and axially towards the exit part 104 extending support shoulder 122 about. The support shoulder 122 supports the inner ring 110 of the deep groove ball bearing 108 radially inwards. The leg section goes radially outside 120 in a circular and axially towards the exit part 104 extending shoulder section 124 about.

The lid section 118 is ring-shaped and has an L-shaped cross section with a radially extending cover plate 126 on. The cover plate goes radially outside 126 in a circular shape and extending axially from the input part 102 groundbreaking lid shoulder 128 about. The end of the axially extending shoulder section 124 of the flange section 116 and a radially outer portion of the lid portion 118 lie against each other and are firmly connected, welded in the present case. The flange section 116 and the lid section 118 delimit a toroidal recording space 130 ,

The output part 104 has a flange part 132 and a flywheel part 134 on. The flange part 132 and the flywheel part 134 are firmly connected, riveted in the present case. The flywheel part 134 has a bowl-like shape. The flywheel part 134 is in sections axially next to the cover section 118 arranged. The lid shoulder 128 of the lid section 118 delimits a space in which the flywheel part 134 is arranged.

Between the entrance part 102 and the output part 104 a spring damper device is effective. The spring-damper device has a spring device with arc springs, such as 136 , on. The bow springs 136 are in the recording room 130 arranged. The bow springs 136 are supported on the one hand on the flange section 116 and the lid portion 118 of the entrance part 102 and on the other hand on the flange part 132 of the output part 104 from. The spring damper device has one Friction device with a friction ring 138 on. The friction device is on the radially inner edge of the cover section 118 arranged.

In a radially outer end area of the cover plate 126 , radially inside and spaced from the lid shoulder 128 is an annular elevation as a support surface 140 of the entrance part 102 educated. The support surface 140 is in the direction of the flywheel part 134 educated. In a radially outer end region of the flywheel part 134 is a circumferential groove 142 brought in. The groove 142 is opposite the support surface in the axial direction 140 arranged. The support surface is in the radial direction 140 and the groove 142 approximately the same distance from the axis of rotation 106 away. The groove 142 is in the direction of the support surface 140 open.

In the groove 142 is an elastomer ring all around 144 used. The elastomer ring 144 is a tilt play limiter, which starts at a predetermined tilt angle between the input part 102 and the output part 104 is effective and the angular mobility between the input part 102 and the output part 104 limited by the elastomer ring 144 and the support surface 140 are in contact with each other from the predetermined tilt angle. The angular mobility between the input part 102 and the output part 104 results from the previously described angular mobility between the axis of rotation of the inner ring 110 and the axis of rotation of the outer ring 112 of the deep groove ball bearing 108 ,

The elastomer ring 144 has a contact area all around 146 on that towards the support surface 140 is convexly curved. A radially inner part and a radially outer part of the curved contact area 146 lie on the flywheel part 134 next to the groove 142 on. The contact area 146 acts like a disc spring. Will the contact area 146 from the support surface 140 When a force is applied, the contact area deforms 146 elastic. On the of the support surface 144 opposite side of the contact area 146 goes the contact area 146 in a circumferential fork-shaped fastening area 148 about. The attachment area 148 is in the groove 142 of the flywheel part 134 pressed. The fact that the radially inner part and the radially outer part of the curved contact area 146 on the flywheel part 134 is the depth of penetration of the fastening area 148 in the groove 142 limited.

Between the support surface 140 of the lid section 118 and the contact area 146 of the elastomer ring 144 is an active gap 150 trained as long as the input part 102 and the output part 104 are not tilted towards each other. As long as the input part 102 and the output part 104 are not tilted to each other, the active gap 150 a width a. The active gap 150 decreases with increasing tilt of the input section 102 relative to the output part 104 , From a predetermined tilt angle between the input part 102 and the output part 104 come the support surface 140 and the contact area 146 for mutual investment. Through the previously described mode of action of the contact area 146 this can change if there is a further tilting between the input part 102 and the output part 104 limited elastic deformation. Because of the elastomer ring 144 less rigidity than the flywheel part 134 the mutual contact is cushioned and preferably damped. A hard hit of the lid section 118 to the flywheel part 134 is avoided, so the deep groove ball bearing 108 is protected from excessive stress.

In a modification of the first embodiment, the tilt play limiter is a plastic ring with similar or the same dimensions and the same function as the elastomer ring described above 144 , In further modifications of the first embodiment, the tilt play limiter consists of several individual elements made of elastomer or plastic attached to the circumference. These preferably largely correspond to the described first exemplary embodiment in terms of cross section and function. Instead of a circumferential groove, an opening per individual element is then preferably provided in the flywheel part.

2 shows one as a dual mass flywheel 200 trained torsional vibration damper according to a second embodiment. The structure and operation of the dual mass flywheel 200 correspond to the dual-mass flywheel except for the differences described below 100 of the first embodiment.

The dual mass flywheel 200 has an input part 202 and an output part 204 with a common axis of rotation 206 on. For mutually rotatable mounting of the input part 202 and the output part 204 serves a deep groove ball bearing 208 , The deep groove ball bearing 208 has an inner ring 210 , an outer ring 212 and bullets like 214 , on, with an axis of rotation of the inner ring 210 and an axis of rotation of the outer ring 212 are mutually angularly movable.

The entrance part 202 has a flange portion 216 and a lid section 218 on. The flange section 216 has a radially extending leg portion 220 on. The leg section goes radially inside 220 in a support shoulder 222 to support the inner ring 210 about. The leg section goes radially outside 220 in yourself axially in the direction of the exit part 204 extending shoulder section 224 about.

The lid section 218 has a radially extending cover plate 226 on. The cover plate goes radially outside 226 in a circular shape and extending axially from the input part 202 groundbreaking lid shoulder 228 about. The flange section 216 and the lid section 218 delimit a toroidal recording space 230 ,

The output part 204 has a flange part 232 and a flywheel part 234 on. The flange part 232 and the flywheel part 234 are firmly connected. The flywheel part 234 is in sections axially next to the cover section 218 arranged.

Between the entrance part 202 and the output part 204 is a spring damper device with bow springs, such as 236 , effective. The bow springs 236 are in the recording room 230 arranged. The spring-damper device has a friction device with a friction ring 238 on.

In a radially outer end area of the cover plate 226 , radially inside and spaced from the lid shoulder 228 is an annular elevation as a support surface 240 of the entrance part 202 educated. The support surface 240 is in the direction of the flywheel part 234 educated. In a radially outer end region of the flywheel part 234 is one towards the lid section 218 pointing circumferential lip 242 with a circumferential groove 244 arranged. The groove 244 is in the radial direction in the lip 242 formed and radially further outside than the support surface 240 arranged.

In the groove 244 is a disc spring all round 246 clipped. The disc spring 246 is a tilt play limiter, which starts at a predetermined tilt angle between the input part 202 and the output part 204 is effective and the angular mobility between the input part 202 and the output part 204 limited.

The disc spring 246 has a contact area all around radially on the inside 248 on that towards the support surface 240 has. The contact area goes radially outside 248 in a circumferential curved fastening area 250 about. The attachment area 250 is in the groove 244 of the flywheel part 234 pressed in, clipped in the present case. The contact area 248 is axially spaced from the flywheel part 234 arranged. Will the contact area 248 from the support surface 240 When a force is applied, the contact area deforms 248 elastic.

Between the support surface 240 of the lid section 218 and the contact area 248 the disc spring 246 is an active gap 252 trained as long as the input part 202 and the output part 204 are not tilted towards each other. As long as the input part 202 and the output part 204 are not tilted to each other, the active gap 252 a width a. The active gap 252 decreases with increasing tilt of the input section 202 relative to the output part 204 , The support surface comes from a predetermined tilt angle 240 the disc spring 246 and the contact area 248 of the lid section 218 for mutual investment. The contact area 248 can result in a further tilting between the input part 202 and the output part 204 limited elastic deformation.

In a modification of the second embodiment, the plate spring is clipped into a groove in the cover section and the support surface is formed on the flywheel part.

3 shows one as a dual mass flywheel 300 trained torsional vibration damper according to a third embodiment. The structure and operation of the dual mass flywheel 300 correspond to the dual-mass flywheel except for the differences described below 100 of the first embodiment.

The dual mass flywheel 300 has an input part 302 and an output part 304 with a common axis of rotation 306 on. For mutually rotatable mounting of the input part 302 and the output part 304 serves a deep groove ball bearing 308 with an inner ring 310 , an outer ring 312 and bullets like 314 , with an axis of rotation of the inner ring 310 and an axis of rotation of the outer ring 312 are mutually angularly movable.

The entrance part 302 has a flange portion 316 and a lid section 318 on. The flange section 316 has a radially extending leg portion 320 on. The leg section goes radially inside 320 in a support shoulder 322 to support the inner ring 310 about. The leg section goes radially outside 320 in an axially towards the exit part 304 extending shoulder section 324 about.

The lid section 318 has a radially extending cover plate 326 on. The cover plate goes radially outside 326 in a circular shape and extending axially from the input part 302 groundbreaking lid shoulder 328 about. The flange section 316 and the lid section 318 delimit a toroidal recording space 330 ,

The output part 304 has a flange part 332 and a flywheel part 334 on. The flange part 332 and the flywheel part 334 are firmly connected. The flywheel part 334 is in sections axially next to the cover section 318 arranged.

Between the entrance part 302 and the output part 304 is a spring damper device with bow springs, such as 336 , effective. The bow springs 336 are in the recording room 330 arranged. The spring-damper device has a friction device with a friction ring 338 on.

In a radially outer end region of the flywheel part 334 is an annular elevation as a support surface 340 educated. The support surface 340 is slightly inclined in relation to the radial direction. The support surface 340 points towards the lid section 318 , In a radially outer end region of the cover section 318 is one in the direction of the flywheel part 334 pointing circumferential groove 342 brought in. The groove 342 is formed in the axial direction and radially further outside than the support surface 340 arranged.

In the groove 342 is an elastomer ring all around 344 used, preferably pressed. The elastomer ring 344 has several fingers spread over its circumference 346 trained clips on. The finger 346 point in the direction of the flywheel part 334 , A disc spring 348 is from the fingers 346 fixed in radial and axial direction. The elastomer ring 344 with your fingers 346 and the disc spring 348 together form a tilt limiter 350 , The tilt game limiter 350 is from a predetermined tilt angle between the input part 302 and the output part 304 effective and thereby the angular mobility between the input part 302 and the output part 304 limited. The angular mobility between the input part 302 and the output part 304 results from the previously described angular mobility between the axis of rotation of the inner ring 310 and the axis of rotation of the outer ring 312 of the deep groove ball bearing 308 ,

The disc spring 348 has a contact area all around radially on the inside 352 on that towards the support surface 340 has. The contact area 352 is axially spaced from the lid portion 318 arranged. Will the contact area 352 from the support surface 340 When a force is applied, the contact area deforms 352 elastic. The contact area goes radially outside 352 in a circumferential fastening area 354 over that of your fingers 346 is held. The fingers are here 346 in corresponding openings in the fastening area 354 clipped. Will the contact area 352 from the support surface 340 When a force is applied, the contact area deforms 352 elastic.

Between the support surface 340 of the lid section 318 and the contact area 352 the disc spring 348 is an active gap 356 trained as long as the input part 302 and the output part 304 are not tilted towards each other. As long as the input part 302 and the output part 304 are not tilted to each other, the active gap 356 a width a. The active gap 356 decreases with increasing tilt of the input section 302 relative to the output part 304 , From a predetermined tilt angle between the input part 302 and the output part 304 come the support surface 340 and the contact area 352 for mutual investment. In the event of further tilting between the input part 302 and the output part 304 becomes the disc spring 348 limited elastic deformation. Because the disc spring 348 less rigidity than the flywheel part 334 the mutual contact is cushioned and preferably damped. A hard hit of the lid section 318 to the flywheel part 334 is avoided.

In a modification of the third exemplary embodiment, the tilt play limiter comprises a plastic ring with fingers and a plate spring with the same dimensions and the same function as the tilt play limiter described above 350 , In further modifications of the first exemplary embodiment, the tilt play limiter comprises a plurality of individual elements made of elastomer or plastic attached to the circumference, each with at least one finger for fastening a plate spring. These individual elements preferably largely correspond to the described third exemplary embodiment with regard to their function. Instead of a circumferential groove, an opening per individual element is then preferably provided in the flywheel part.

4 shows one as a dual mass flywheel 400 trained torsional vibration damper according to a fourth embodiment. The structure and operation of the dual mass flywheel 400 correspond to the dual-mass flywheel except for the differences described below 100 of the first embodiment.

The dual mass flywheel 400 has an input part 402 and an output part 404 with a common axis of rotation 406 on. For mutually rotatable mounting of the input part 402 and the output part 404 serves a deep groove ball bearing 408 with an inner ring 410 , an outer ring 412 and bullets like 414 , with an axis of rotation of the inner ring 410 and an axis of rotation of the outer ring 412 are mutually angularly movable.

The entrance part 402 has a flange portion 416 and a lid section 418 on. The flange section 416 has a radially extending leg portion 420 on. The leg section goes radially inside 420 in a support shoulder 422 to support the inner ring 410 about. The leg section goes radially outside 420 in an axially towards the exit part 404 extending shoulder section 424 about.

The lid section 418 has a radially extending cover plate 426 on. The cover plate goes radially outside 426 in a circular shape and extending axially from the input part 402 groundbreaking lid shoulder 428 about. The flange section 416 and the lid section 418 delimit a toroidal recording space 430 ,

The output part 404 has a flange part 432 and a flywheel part 434 on. The flange part 432 and the flywheel part 434 are firmly connected. The flywheel part 434 is in sections axially next to the cover section 418 arranged.

Between the entrance part 402 and the output part 404 is a spring damper device with bow springs, such as 436 , effective. The bow springs 436 are in the recording room 430 arranged. The spring-damper device has a friction device with a friction ring 438 on.

In a radially outer end area of the cover plate 426 , radially inside and spaced from the lid shoulder 428 is an annular elevation as a support surface 440 of the entrance part 402 educated. The support surface 440 is in the direction of the flywheel part 434 educated. In a radially outer end region of the flywheel part 434 is a circumferential groove 442 brought in. The groove 442 is opposite the support surface in the axial direction 440 arranged. The support surface is in the radial direction 440 and the groove 442 approximately the same distance from the axis of rotation 406 away. The groove 442 is in the direction of the support surface 440 open.

In the groove 442 is a meandering wire ring all around 444 , made from a spring wire. The wire ring 444 is a tilt play limiter, which starts at a predetermined tilt angle between the input part 402 and the output part 404 is effective.

The wire ring 444 has a wave shape formed all around in the axial direction, the outer contour of the wire ring being viewed in the radial direction 444 lies on a virtual circular cylinder surface.

The the lid section 418 facing wave crests of the wire ring 444 form several contact areas 446 that towards the support surface 440 are convexly curved. The the lid section 418 facing away troughs of the wire ring 444 form several fastening areas 448 , The attachment areas 448 are in the groove 442 of the flywheel part 434 pressed.

Between the support surface 440 of the lid section 418 and the contact areas 446 of the wire ring 444 is an active gap 450 trained as long as the input part 402 and the output part 404 are not tilted towards each other. As long as the input part 402 and the output part 404 are not tilted to each other, the active gap 450 a width a. The active gap 450 decreases with increasing tilt of the input section 402 relative to the output part 404 , From a predetermined tilt angle between the input part 402 and the output part 404 come the support surface 440 and the contact areas 446 for mutual investment. Through the waveform of the wire ring 444 this can change if there is a further tilting between the input part 402 and the output part 404 limited elastic deformation. Because of the wire ring 444 less rigidity than the flywheel part 434 the mutual contact is cushioned and preferably damped. A hard hit of the lid section 418 to the flywheel part 434 is avoided.

LIST OF REFERENCE NUMBERS

100

Torsional vibration damper, dual mass flywheel

102

introductory

104

output portion

106

axis of rotation

108

Bearing device, deep groove ball bearing

110

inner ring

112

outer ring

114

Bullet

116

flange

118

cover section

120

leg portion

122

supporting shoulder

124

shoulder portion

126

cover disk

128

cover shoulder

130

accommodation space

132

flange

134

Inertia part

136

bow spring

138

friction ring

140

supporting

142

groove

144

Tilt clearance limiter, elastomer ring

146

contact area

148

fastening area

150

working gap

200

Torsional vibration damper, dual mass flywheel

202

introductory

204

output portion

206

axis of rotation

208

Bearing device, deep groove ball bearing

210

inner ring

212

outer ring

214

Bullet

216

flange

218

cover section

220

leg portion

222

supporting shoulder

224

shoulder portion

226

cover disk

228

cover shoulder

230

accommodation space

232

flange

234

Inertia part

236

bow spring

238

friction ring

240

supporting

242

lip

244

groove

246

Tilt clearance limiter, disc spring

248

contact area

250

fastening area

252

working gap

300

Torsional vibration damper, dual mass flywheel

302

introductory

304

output portion

306

axis of rotation

308

Bearing device, deep groove ball bearing

310

inner ring

312

outer ring

314

Bullet

316

flange

318

cover section

320

leg portion

322

supporting shoulder

324

shoulder portion

326

cover disk

328

cover shoulder

330

accommodation space

332

flange

334

Inertia part

336

bow spring

338

friction ring

340

supporting

342

groove

344

elastomer ring

346

finger

348

Belleville spring

350

Kippspielbegrenzer

352

contact area

354

fastening area

356

working gap

400

Torsional vibration damper, dual mass flywheel

402

introductory

404

output portion

406

axis of rotation

408

Bearing device, deep groove ball bearing

410

inner ring

412

outer ring

414

Bullet

416

flange

418

cover section

420

leg portion

422

supporting shoulder

424

shoulder portion

426

cover disk

428

cover shoulder

430

accommodation space

432

flange

434

Inertia part

436

bow spring

438

friction ring

440

supporting

442

groove

444

Tilting game limiter, wire ring

446

contact area

448

fastening area

450

working gap

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included 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.

Patent literature cited

• DE 102013210492 A1 [0002]
• DE 102017117853 A1 [0003]

Claims (10)

Torsional vibration damper (100, 200, 300, 400), in particular dual-mass flywheel, the torsional vibration damper (100, 200, 300, 400) having an input part (102, 202, 302, 402), an output part (104, 204, 304, 404), a common axis of rotation (106, 206, 306, 406) about which the input part (102, 202, 302, 402) and the output part (104, 204, 304, 404) can be rotated together and by means of a bearing device (108, 208, 308 , 408) can be rotated relative to one another to a limited extent and can be tilted relative to one another, a spring-damper device which acts in the circumferential direction between the input part (102, 202, 302, 402) and the output part (104, 204, 304, 404), and a radial one tilting play limiter (144, 246, 350, 444) spaced from the bearing device (108, 208, 308, 408), which, starting from a predetermined tilting angle, between the input part (102, 202, 302, 402) and the output part (104, 204, 304 , 404) is effective, characterized in that the tilt play limiter (144, 246, 350, 444) at least has an elastically deformable component formed separately from the input part (102, 202, 302, 402) and output part (104, 204, 304, 404). Torsional vibration damper (100, 200, 300, 400) after Claim 1 , characterized in that the elastically deformable component of the tilt play limiter (144, 246, 350, 444) has a contact area (146, 248, 352, 446) which, when the predetermined tilt angle is reached between the input part (102, 202, 302, 402 ) and the output part (104, 204, 304, 404) a support surface (140, 240, 340, 440) of the input part (102, 202, 302, 402) or the output part (104, 204, 304, 404) contacted. Torsional vibration damper (100, 200, 300, 400) after Claim 1 or 2 , characterized in that when the predetermined tilt angle is exceeded, the elastically deformable component is elastically deformed. Torsional vibration damper (100) according to at least one of the Claims 1 to 3 , characterized in that the elastically deformable component is an elastomer ring (144) or a plastic ring, in particular the elastomer ring (144) or the plastic ring is arranged in sections in a groove (142) of a flywheel part (134) of the starting part (104), and in particular a cover section (118) of the input part (102) has a support surface (140). Torsional vibration damper according to at least one of the Claims 1 to 3 , characterized in that the tilt play limiter has a plurality of individual elements made of elastomer or plastic as elastically deformable components, in particular the individual elements are arranged in openings in a flywheel part of the output part, and in particular a cover section of the input part has a support surface or a plurality of support surfaces. Torsional vibration damper (200, 300) according to at least one of the Claims 1 to 3 , characterized in that the tilt play limiter (246, 350) has a plate spring (246, 348) as an elastically deformable component. Torsional vibration damper (200) after Claim 6 , characterized in that the plate spring (246) is arranged, in particular clipped, in sections in a groove (244) of a flywheel mass part (234) of the output part (204) or in a groove of the input part. Torsional vibration damper (300) Claim 6 , characterized in that the plate spring (348) is held by an elastomer ring (344) or by a plastic ring, in particular the elastomer ring (344) is arranged in sections in a groove (342) of the input part (302), and in particular a flywheel part (334 ) of the output part (304) has a support surface (340). Torsional vibration damper (300) Claim 8 , characterized in that the elastomer ring (344) or the plastic ring have a plurality of fastening means, in particular fingers (346), for fixing the plate spring (348). Torsional vibration damper (400) according to at least one of the Claims 1 to 3 , characterized in that the elastically deformable component is a wire ring (444), in particular the wire ring (444) is arranged in sections in a groove (442) of a flywheel part (434) of the output part (404), and in particular a cover section (418) of the Input part (402) has a support surface (440).

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