Provided is a vibration damping device including guide surfaces that are concave surfaces formed in a support member so as to curve toward the outer periphery of the support member; mass bodies that, as the support member rotates, roll on the guide surfaces while being pressed against the guide surfaces by a centrifugal force; and inertia rings that are rotatably coupled to the mass bodies and swing about the center of rotation of the support member. When the vibration damping device is in equilibrium, the center of gravity of each mass body is located radially outward of the joint position between the mass body and the inertia rings. As the support member rotates, the inertia rings swing relative to the support member about the center of rotation of the support member, and the mass bodies roll on the guide surfaces.

Circular force generator (CFG) devices, systems, and methods are disclosed having indirectly driven imbalanced rotors for generating vibrations and/or imparting vibration control. A CFG device (10) includes a first set of imbalanced rotors (12) disposed about a center point and a second set of imbalanced rotors (12) disposed about the center point. The first set of imbalanced rotors is configured to co-rotate synchronously. The second set of imbalanced rotors is configured to co-rotate synchronously. The first and second sets of imbalanced rotors are configured to create a controllable rotating force vector having a controllable magnitude and phase about the center point. A CFG system includes a controller and one or more CFG devices configured to receive control commands from the controller. A method of generating a force via a CFG device includes receiving a force command and generating a force in response to receiving the force command.

A rotating inertia mass damper of a damper device comprises a planetary gear including a driven member that has external teeth and that serves as a sun gear; a plurality of pinion gears; first and second input plate members that are configured to support the plurality of pinion gears in a rotatable manner and that serve as a carrier; and a ring gear that is engaged with the plurality of pinion gears and that serves as a mass body. The ring gear has two gear main bodies that are arranged along an axial direction of the planetary gear and that are coupled with each other. Internal teeth of the two gear main bodies are shifted to each other in a circumferential direction of the gear main bodies.

A drive member of a damper device includes a first input plate member and a second input plate member that rotatably support a plurality of pinion gears of a planetary gear of a rotary inertia mass damper. A driven member includes an outer teeth gear portion that meshes with the pinion gear in an outer circumferential portion thereof and is disposed between the first and the second input plate members in an axial direction so as to work as a sun gear of the planetary gear. A stopper is configured to restrict the relative rotation between the drive member and the driven member and includes a contact portion arranged in the outer circumferential portion of the driven member so as to contact with the first input plate member.

A damper device includes first inner springs configured to transmit a torque between a drive member and an intermediate member, second inner springs configured to transmit a torque between the intermediate member and a driven member, and a rotary inertia mass damper including a sun gear serving as a mass body rotating with relative rotation of the drive member to the driven member. The rotary inertia mass damper is provided in parallel to a torque transmission path including the intermediate member, the first inner springs and the second inner springs. A damping ratio of the intermediate member determined based on a moment of inertia J.sub.2 of the intermediate member and rigidities k.sub.1 and k.sub.2 of the first and the second inner springs and is less than a value.

A torsional vibration damper in which noise and vibrations in a planetary gear unit are suppressed is provided. In a planetary gear unit, as an inertial element is oscillated to establish an inertial torque by a relative rotation between a sun gear and a ring gear. Pinion gears are interposed between the sun gear and the ring gear at predetermined intervals, and gear dimensions of one of the pinion gears and gear dimensions of another one of the pinion gears are different from each other.

The centrifugal mass arrangement for the balancing of rotational accelerations of an engine housing of a reciprocating-piston engine, such as an internal combustion engine, is equipped with a hollow cylindrical housing provided for fastening to the engine housing and has a circumferential wall with an inner side, and with a centrifugal mass carrier arranged rotatably in the housing and coupled to the drive shaft for co-rotation therewith. The centrifugal mass carrier has at least two diametrically oppositely situated ends. A roller disk with a circumferential surface is arranged on each end of the centrifugal mass carrier. Each roller disk is mounted rotatably on the respective end of the centrifugal mass carrier and is supported by the circumferential surface against the inner side of the circumferential wall of the housing and, during rotation of the centrifugal mass carrier, rolls on the inner side of the circumferential wall of the housing.

A powertrain includes an engine having a crankshaft, and a transmission having an input. A vibration absorption assembly includes a mechanical connection system providing a first connection node, a second connection node, and a third connection node. The crankshaft is connected to a first one of the connection nodes. The input of the transmission is connected to a second one of the connection nodes. A centrifugal pendulum absorber is connected to a third one of the connection nodes. One of the connection nodes is a mechanically advantaged node. The centrifugal pendulum absorber is connected to the mechanically advantaged node.

A powertrain includes an engine having a crankshaft, and a transmission having an input. A vibration absorption assembly includes a mechanical connection system providing a first connection node, a second connection node, and a third connection node. The crankshaft is connected to a first one of the connection nodes. The input of the transmission is connected to a second one of the connection nodes. A centrifugal pendulum absorber is connected to a third one of the connection nodes. One of the connection nodes is a mechanically advantaged node. The centrifugal pendulum absorber is connected to the mechanically advantaged node.

A torsional vibration damping arrangement for the powertrain of a vehicle comprises an input region) to be driven for rotation around a rotational axis (A) and an output region), there being provided between the input region) and the output region) a first torque transmission path) and, parallel thereto, a second torque transmission path) and a coupling arrangement). A phase shifter arrangement) is provided in the first torque transmission path), and a torsional vibration modification arrangement) is arranged in the first torque transmission path) between the phase shifter arrangement) and the coupling arrangement) and/or a torsional vibration modification arrangement) is arranged in the second torque transmission path) upstream of the coupling arrangement).