Abstract: The invention relates to a torsional damper (210) in a clutch disc arrangement (200) arranged to indicate damping performance of the torsional damper (210). The torsional damper (210) comprises a driven plate (211), an output hub (212), intermediate friction plates (213) arranged on either side of the driven plate (211) and a resilient member (214) arranged to press the intermediate friction plates (213) against the driven plate (211) or against the output hub (212) with a pressure force. The intermediate friction plates (213) and the resilient member (214) are rotationally fixed to the output hub (212) or the driven plate (211) forming a rotationally fixed stack (213, 214, 212; 213, 214, 211). The rotationally fixed stack (213, 214, 212; 213, 214, 211) comprises a detection friction plate (215) rotatably decoupled from the rotationally fixed stack (213, 214, 212; 213, 214, 211) and arranged in the rotationally fixed stack (213, 214, 212; 213, 214, 211).

Abstract: A torsional damping device (110) includes a movable torque input element (130, 140), a movable torque output element (150), at least one phasing member (320,340) and at least one group of elastic members (250, 260) mounted between the torque input element and torque output element. The at least one group of elastic members acts against rotation of the torque input element and the torque output element with respect to one another. The elastic members of the at least one group of elastic members are arranged in series by the at least one phasing member (320, 340) so that the elastic members of the at least one group of elastic members deform in phase with one another. The torque input element having at least one stop member (620) limiting rotation of the torque input elememt relative to the output element and relative to the at least one phasing member.

Abstract: A vibration damping device for a motor vehicle, features a first movable element (13, 14) and a second movable element (15, 16) both rotatable around an axis X, at least one group of elastic members (25, 26) mounted between the first movable element and the second movable element and acting against rotation of the first movable element and second element with respect to one another, and a phasing member (32, 33) rotationally movable around the axis X. The first movable element (13, 14) and the second movable element (15, 16) are coaxial and capable of transmitting a torque. The phasing member (32, 33) includes a first portion (32) and a second portion (33), for arranging the elastic members of the at least one group in series so that the elastic members of each group deform in phase with one another.

Abstract: A torsional vibration damper having enhanced vibration damping performance is provided. The torsional vibration damper comprises: a vacant area existing between an outer circumference of the sun gear and an inner circumference of the ring gear outside of a revolving range of the planetary gears revolved as a result of relative rotation between the sun and the ring gear; and a mass increasing portion that is formed on the rotary member other than an input element and an output element within the vacant area in such a manner as to protrude from the rotary member.

Abstract: A damper includes a first, second, and third rotation member rotatable around a rotation axis, a first elastic portion interposed between the first rotation member and the second rotation member and elastically deformed by a relative rotation between the first rotation member and the second rotation member, a second elastic portion interposed between the second rotation member and the third rotation member and elastically deformed by a relative rotation between the second rotation member and the third rotation member, and a dynamic vibration absorber. The dynamic vibration absorber includes a rolling element that is positioned at an inner side relative to the first elastic portion and the second elastic portion in a radial direction of the rotation axis, and is rotatable relative to the second rotation member.

Abstract: A friction assembly for a torque converter, including: a side plate for a damper in the torque converter; a plate; an output hub for connection to an input shaft for a transmission; and a diaphragm spring. The side plate and the plate are fixedly connected to a turbine shell for the torque converter. The diaphragm spring is directly engaged with the output hub so that the diaphragm spring rotates with the output hub and is axially displaceable with respect to the output hub. The diaphragm spring is directly engaged with the side plate and the plate so that the diaphragm spring is axially restrained by the side plate. The plate and is rotatable with respect to the side plate and the plate.

Abstract: A hysteresis assembly, including: first, second, and third plates; at least one fastener connecting the first and third plates; and, at least one resilient element. The resilient element is: disposed between the first and second plates; disposed about the fastener; and arranged to urge the second plate into frictional contact with the third plate. A damper assembly, including: first and second cover plates arranged to receive torque; a flange axially disposed between the cover plates; at least one first resilient element engaged with the cover plates and the flange and arranged to transmit the torque to the flange; at least one fastener connecting the cover plates and passing through the flange; and at least one second resilient element. The resilient element is: disposed between the first cover plate and the flange; disposed about the fastener; and arranged to urge the flange into frictional contact with the second cover plate.

Abstract: A torsion vibration damping apparatus can prevent the strengths of its projection portions from being decreased even if the torsion vibration damping apparatus is made small in size, and can damp torsion vibration caused by a transitional torque when a hub member is rotated in the positive side relatively rotated with respect to a rotation member, thereby making it possible to enhance a damping property of the torsion vibration. The projection amount of a projection portion 40A circumferentially projecting in the positive side from the radially center axis O of the projection portion of a hub flange 40 is formed smaller than the projection amount of the projection 40A circumferentially projecting in the negative side from the radially center axis O of the projection portion.

Abstract: The torque fluctuation absorber includes a flywheel fixed on a first rotating shaft by a fixation member, a damper unit connected with a second rotating shaft and absorbs fluctuation of torque occurred between the first rotating shaft and the second rotating shaft by elastic force, and a limiter unit provided on a power transmission path between the flywheel and the damper unit and inducing a slide when the fluctuation of the torque exceeded a predetermined value. A predetermined member rotates with the first rotating shaft on a power transmission path between the first rotating shaft and the limiter unit. The predetermined member has a side plate at the damper unit and a guide portion that prevents movement radially of a hub member, and the guide portion is provided at radially internal side of the fixation member.

Abstract: In this damper mechanism, when small fluctuations in torque input to the damper mechanism occur, small hysteresis torque is produced as a result of pressure contact between a radial plate and a first friction section. Consequently, the small torque fluctuations can be damped between the radial plate and the first friction region of the damper mechanism and can be output to an input shaft. In addition, along the direction of relative rotation of an annular plate and the radial plate, the friction coefficients of the annular plate and the radial plate become larger as the torsion angles of both plates become larger. Therefore, even when torque fluctuations become large, the hysteresis torque can be produced in accordance with the magnitude of the torque fluctuations.

Abstract: The present invention broadly comprises a vibration damper assembly for a torque transmitting device. The assembly includes a thrust washer secured by first and second components of a vibration damper and a hub secured by the first and second components. The vibration damper, thrust washer, and hub are secured in a fixed position with respect to one another. In some aspects, the torque transmitting device comprises a longitudinal axis and the thrust washer comprises a hub segment having substantially a toroidal shape and at least one retainer segment extending outward, with respect to the axis, from the hub segment. At least a portion of the at least one retainer segment is disposed between the first and second components.

Abstract: A process for producing a clutch friction plate in which a plurality of friction material segments are bonded to an annular flat face of an annular core plate so that oil channels are formed between the segments, the process including: a step of forming a plurality of strip-shaped friction materials by cutting a band-shaped friction material along its longitudinal direction; a step of aligning and holding portions, corresponding to the segments, of leading edge parts of the materials in positions above the core plate while positioning the portions in the peripheral direction and in the direction along one diameter of the core plate; a step of forming the segments by cutting off the leading edge parts of the materials positioned above the core plate along a cutting-off line that includes at least an arc line that follows the outer periphery of the core plate, and a step of pressing and bonding the segments onto the face coated with an adhesive.

Abstract: A torsional vibration damper includes: a primary mass defining a substantially, ring-shaped chamber that is divided into at least two portions; a secondary mass relatively rotatably connected to the primary mass; and a plurality of damping units disposed in the divided portion of the ring-shaped chamber for coupling the primary and secondary masses to each other in a rotatable elastic manner. Each of the damping units includes a plurality of coil springs, and outer and inner wedge-shaped friction guides. The coil springs are situated in series and disposed one after the other within the divided portions of the ring-shaped chamber. The outer and inner wedge-shaped friction guides face each other along facing surfaces thereof. Each of the facing surfaces of the outer and inner wedge-shaped friction guides are entirely slanted with respect to a radial direction of the primary mass.

Abstract: A damper mechanism 6 is provided to transmit torque while absorbing and damping torsional vibrations. A small coil spring 45 achieves characteristics of a low rigidity in a small torsion angle region of the torsion characteristics when compressed by rotary members. A coil spring 33 achieves characteristics of a high rigidity in a large torsion angle region of the torsion characteristics when compressed by the rotary members rotating relatively to each other. A frictional resistance generating mechanism 7 generates a frictional resistance while each spring is being compressed. Owing to a rotating-direction space 79, the frictional resistance generating mechanism 7 does not operate in the second stage of the torsion characteristics and also does not in the first stage while a torsion angle is in a predetermined range.

Abstract: A process for producing a clutch friction plate in which a plurality of friction material segments are bonded to an annular flat face of an annular core plate so that oil channels are formed between the segments, the process including: a step of forming a plurality of strip-shaped friction materials by cutting a band-shaped friction material along its longitudinal direction; a step of aligning and holding portions, corresponding to the segments, of leading edge parts of the materials in positions above the core plate while positioning the portions in the peripheral direction and in the direction along one diameter of the core plate; a step of forming the segments by cutting off the leading edge parts of the materials positioned above the core plate along a cutting-off line that includes at least an arc line that follows the outer periphery of the core plate, and a step of pressing and bonding the segments onto the face coated with an adhesive.

Abstract: The invention eliminates the need of handling an engine in a process for assembling a torsion damper which couples the engine with a power transmission system and a torque limiter. In a damper unit with a torque limiter positioned between an output shaft of an engine and a power transmission shaft of a power transmission system, the damper unit includes a fly wheel damper, a torsion damper and a torque limiter. The torque limiter of the damper unit is coupled to the torsion damper with a set load applied thereto such that the torque limiter and the torsion damper are combined to form an assembly. The torsion damper and the torque limiter can be assembled by handling, independently of the engine, only components which are smaller and lighter than an engine. This improves the efficiency of the assembling operation of the damper unit with the torque limiter.

Abstract: In a stator in which a damper mechanism is provided between a ratchet one-way clutch mechanism and a vane wheel, the damper mechanism is provided with a friction element.

Abstract: A flywheel damper 11 to which torque is transmitted from a crankshaft 2 of an engine, includes a second flywheel assembly 5, a damper mechanism 6, and a support plate 39. The damper mechanism 6 elastically connects the second flywheel assembly to the crankshaft 2 in a rotating direction. The support plate 39 is attached to the crankshaft 2 and supports the second flywheel assembly 5 on the crankshaft 2. The support plate 39 has an axial extension 39f attachable to and detachable from the second flywheel assembly 5 in the axial direction.

Abstract: A torque converter with a lockup damper is provided to improve the vibration damping function. The torque converter 1 has the lockup device 7 for mechanically connecting and disconnecting a front cover 11 and a turbine 22, which includes a clutch mechanism and a damper mechanism. A friction generating mechanism 45 is a mechanism that generates friction resistance when the lockup damper operates, and includes a friction washer 52, which constitutes a friction surface, and a micro twisting angle adjustment gap 56, which is arranged to prevent the friction washer 52 from operating within a range of micro twisting angles.

Abstract: Disclosed herein is a friction torque device with an improved damper for attenuating torsional vibrations. The improved damper provides the desired axial load for damping while reducing the weight, cost, complexity and size of a driven disk for a friction torque device. A friction torque device comprises a driving member having of rotation, a cover coupled to the driving member for rotation therewith, a pressure plate coupled to the cover for rotation therewith and a driven disk coupled to an axially extending driven shaft for rotation therewith. The driven disk is interposed between the driving member and the pressure plate, the driven disk includes a rotatable disk assembly and a hub assembly. The driven disk comprises at least one reinforcing plate having a plurality of undulations disposed therein for providing a load between the disk assembly and hub assembly. The reinforcing plate may be coupled to the disk assembly, the hub assembly or the plate may not be attached to another component.

Abstract: A clutch apparatus 1 includes a clutch cover assembly 8 and a damper mechanism 24. The clutch cover assembly 8 includes a pressure plate 51, a clutch cover 28, and a cone spring 52. The damper mechanism 24 includes elastic members 30 that are retained by a crankshaft 2 or the clutch cover assembly 8 and axially releasably engages the other. A release mechanism 10 includes a cover member 57, a release member 60, and a lever member 59. The inner peripheral end of the cover member 57 is supported by a member disposed on a transmission side. The release mechanism 10 moves the plate 51 away from the clutch disk 82 by applying a load to the assembly 8. The relative rotation limiting mechanism connects the assembly 8 to a member disposed on the crankshaft side by the load applied from the release mechanism 10 to the assembly 8.

Abstract: A friction clutch includes a driving gearwheel, a clutch hub, and a clutch cage. The clutch cage and the clutch hub are coupled together by way of non-positive frictional forces in the clutch cage. A driving disc is fixed to the clutch cage, and a gearbox input shaft is in toothed or splined engagement with the clutch hub. Torsional springs are interposed between the clutch cage and a driving gearwheel to permit the driving gearwheel to rotate within a limited range of motion with respect to the clutch cage. The driving gearwheel meshes with a primary gearwheel on a crankshaft. The crankshaft drives rotation of the gearbox input shaft through the driving gearwheel, the torsional springs, the clutch cage, and the clutch hub. A friction device is interposed between a collar of the driving gearwheel and the driving disc. The friction device damps torsional vibrations by non-positively coupling the driving gearwheel with the driving disc in the radial direction.

Abstract: A torsion damping mechanism with a torsion damper with an input side and an output side, where the input side and the output side are connected elastically to each other by spring-type stored energy elements for rotation in common auxiliary mass which can rotate coaxially to the torsion damping mechanism is connected frictionally to the torsion damping mechanism by way of a friction area, where the frictional connection between the torsion damping mechanism and the auxiliary mass has a predetermined frictional moment. When this moment is exceeded during the occurrence of peaks in the torque being applied to the torsion damping mechanism, the auxiliary mass can slip or slips.

Abstract: The invention concerns a vibration damping device (2). This includes at least two elements—a primary element (3.1) and a secondary element (3.2)—, which are limited in movement in relation to each other. The primary element (3.1) and the secondary element (3.2) can be coupled together using a spring coupling. The means to implement spring coupling include at least one spring device (4.1, 4.N).

Abstract: A torsional vibration damper, especially for transmission of torque in a hydrodynamic torque converter, includes a primary side, a secondary side, and a plurality of damper spring arrangements arranged between the primary side and the secondary side such that the primary side is rotatable relative to the secondary side against an urgency of the damper spring arrangement. Each damper spring arrangement has at least one spring and is supported in each circumferential end area at a supporting area of the secondary side and at a first and a second supporting area of the primary side which are arranged on both axial sides of the associated supporting area of the secondary side. The primary side has a substantially annular carrier part and at least one of the first and second supporting areas of the primary side are constructed as separate parts that are connected for rotation with the primary side.

Abstract: A double flywheel vibration damper including two coaxial masses free to rotate relative to each other and acting against elastic parts, in which one of the masses, referred to as the first mass, is intended to be fastened to a drive shaft, whereas the other mass, referred to as the second mass, includes a reaction plate assuring rotational connection to a driven shaft, and in which the first mass has a central hub projecting axially and carrying bearing member operating between the second mass and the central hub to enable the second mass to rotate on the first mass, wherein the central hub comprises two aligned coaxial parts, namely a first hub supporting the second mass rotationally via the bearing member fitted on this first hub, and a second hub intended to be fastened to the drive shaft, and wherein the second hub constitutes an axial spacer between the drive shaft and the first hub. The invention is applicable to motor vehicle transmission systems.

Abstract: A damper disc assembly having multiple embodiments. In one embodiment, spring seats are arranged at opposite ends of coil springs disposed between a power input rotary member and a power output rotary member. Each spring seat has a contacting surface with mutually perpendicular slanting portions. In another embodiment, a modified spring seat determines a phase or orientation of the power input rotary member with respect to the power output rotary member. In a third embodiment, a friction element is formed of resin and includes a friction adjusting element. The body portion of the friction element is made of resin and includes a friction generating surface that contacts a side surface of the sub-plate. The fiction adjusting element is provided in the friction generating surface of the body portion by molding and modifies the friction coefficient thereof. In a fourth embodiment, the friction element has a coating applied to a friction surface which modifies the friction coefficient.

Abstract: A torque damping device including a support disc, a second guide washer provided with pressed sections and an intermediate hub disc. The support disc has elastic clamps acting on the hub disc for pushing the pressed sections towards the hub disc. The invention is particularly applicable to clutch friction for motor vehicles.

Abstract: A clutch disk assembly 1 includes a clutch plate 3, a retaining plate 4, a hub 5 and a large torsion springs 8. The clutch and retaining plates 3 and 4 have first convex portions 13. A first window 17 corresponding to the first convex portion 13 is formed in a flange 5a of the hub 5. The large torsion spring 8 is arranged in the first convex portion 13 and the first window 17 for circumferentially coupling the clutch and retaining plates 4 and 5 to the flange 5a.

Abstract: A double flywheel, the friction members of which comprise a first ring (41) and a second ring (46) which are situated radially one outside the other, the first ring being gripped elastically in frictional contact against a friction face (40) of one of the rotating masses by a closure ring (45), a resiliently acting ring (48) being interposed between this closure ring (45) and the friction ring (46), so as to constitute two-stage friction members having a reduced number of components.

Abstract: A flywheel having to coaxial members, the first member designed to be rotational integral with a drive shaft such as the crankshaft of an internal combustion engine, the second member designed to be connected with a driven shaft such as a gear box. The coaxial members are mounted via a bearing and coupled to each other. The second member forms a reaction plate of a friction clutch having ventilation holes proximate the bearing. The ventilation holes open into the bottom of a groove provided in the second member around the inner edge of the reaction plate radially above the bearing for collecting lubricating agent such as oil escaping from the center of the flywheel.

Abstract: A torsion damper having two coaxial masses defined by a first mass (12) and a second mass (14). The second mass (14) includes a damper plate (28) fixed to the first mass (12). An annular ventilation space (48) is formed between a second platen (27) of the second mass (14) and the damper plate (28) to enhance cooling.

Abstract: A reaction plate for a friction clutch comprising a cover which includes a mounting insert fixed in the body of the reaction plate. The insert includes, on the outer periphery of the reaction plate, a projecting area for mounting the friction clutch cover.

Abstract: A double damped flywheel for a motor vehicle comprises a first mass having a central hub, a second mass, a torsion damper, and a friction device working axially between the first mass and the second mass and having at least one friction ring in contact with a friction surface. The friction ring and the associated friction surface are carried by a support cage which is fitted on a local portion, having an increased radius, of the central hub, this cage being located axially by a transverse thrust plate of the first mass, so that the cage is located between this thrust plate and the anti-friction bearing by which the second mass is mounted on the first mass.

Abstract: The hydrokinetic coupling apparatus includes a housing (12) capable of being rotatably locked on a driving shaft, a turbine wheel (14) capable of being rotatably locked on a driven shaft and a locking clutch (10) acting between the housing (12) and the turbine wheel (14), the said clutch including a piston (2) mounted so as to be axially mobile with respect to the turbine wheel (14), whilst being rotatably locked to the latter, and a counter-piston (3) associated with the housing (12). The piston (12) is interposed axially between the turbine wheel (14) and a mass (3), forming a counter-piston, pivotally mounted on the housing (12). The said mass (3) is coupled elastically to the said housing (12) by means of springs (7) mounted at the outer periphery of the mass (3) between a transverse wall of the housing (12) and a radial projection (31) on the mass (3).

Abstract: Friction clutch, in particular for motor vehicles, consisting of a driving portion as a counterpressure plate, a pressure plate oriented so that it can move axially but not rotationally with respect to the counterpressure plate, a clutch plate with clutch linings which can be fixed between the two and which is located non-rotationally on a drive shaft, whereby the clutch plate is provided if necessary with a load and/or idle damper, whereby there are also pressure elements for the clutch plate and/or the damper. On such a friction clutch, the object of the invention is to realize different, predetermined moments of friction with the identical geometry of the friction device. The invention teaches that this object can be achieved by providing as the pressure element at least one permanent magnet and/or at least one magnet system and/or at least one electrically energized magnetic circuit.