An integrated gear and torsional vibration damper assembly (10, 20, 30, 30) includes a gear (11, 21, 31, 41) having a toothed portion (11a, 21a, 31a, 41a) and a torsional vibration damper (12, 22, 32, 42) supported on the gear (11, 21, 31, 41) for limited rotational and dampened movement relative to each other. The gear (11) may include a hub portion (11b), and the torsional vibration damper (12) may be supported on the hub portion (11b) of the gear (11). Alternatively, the gear (21) may include a hub portion (21b), an intermediate ring (23) may be supported on the hub portion (21b) of the gear (21), and the torsional vibration damper (22) may be supported on the intermediate ring (23). Alternatively, the gear (31) may include a toothed portion (31a) and a hub portion (31b) that extends radially inwardly from the toothed portion (31a) and has an opening (31c) extending therethrough, and the torsional vibration damper (32) may extend through the opening (31c). Alternatively, the gear (41) may include an inner circumferential surface that engages and supports an outer circumferential surface of the torsional vibration damper (41).

A torsional damper assembly includes a hub having an outer periphery, an annular elastomeric element disposed about the outer periphery, and an annular inertia ring disposed about the elastomeric element. The inertia ring has an inner periphery adjacent the elastomeric element. The outer periphery of the hub is provided with a first plurality of surface features and the inner periphery of the inertia ring is provided with a second plurality of surface features. The first plurality of surface features is complementary to and engaged with the second plurality of surface features.

A vibration absorber bush for an inner tube absorber for absorbing torsional and flexural vibrations, for the coaxial assembly in a hollow shaft which is penetrated by a central longitudinal axis includes at least one largely cylindrical first elastic element and a largely cylindrical second elastic element which are in each case disposed to be coaxial with the longitudinal axis and to be mutually adjacent in the radial direction. In embodiments, a reinforcement element is disposed between the elastic elements.

In an aspect, a torsional vibration damper is provided, comprising a hub portion that mounts to a crankshaft, an outer ring that includes an inertial mass, a plurality of radial connectors that are elastically deformable and a plurality of spacers that extend circumferentially between the radial connectors and which are elastically deformable by the radial connectors during flexure thereof. The spacers are non-metallic and dissipate energy from deformation via conversion to heat. The plurality of radial connectors have a circumferential spring rate K1a in bending in a circumferential direction about the axis, and have an axial spring rate K1b in bending in an axial direction, wherein K1b is at least 10 times as large as K1a. The plurality of spacers have a circumferential spring rate Kra in the circumferential direction, and an axial spring rate Krb in bending in the axial direction, wherein Kra is less than 1% of K1a.

In one embodiment, a method for cooling an engine damper, including converting a gas to a liquid, and cooling an engine damper by passing the liquid through a tube portion located between fan air flow and the engine damper.

An air flow generation structural body includes a main body disposed in a gap between an attachment target to which a sealing device is attached and a disc-shaped member that is integrated with a shaft member so as to extend from the shaft member toward an outer periphery side. The shaft member passes through a through-hole in the attachment target and is rotatable around an axis. The main body is attached to the shaft member so as to be rotatable together with the shaft member. The air flow generation structural body further includes a plurality of blade portions formed on an outer peripheral surface g of the main body to generate an air current. Each of the blade portions extends along a centrifugal direction perpendicular to the axis x and is parallel to the axis x.

The disclosed invention is a novel method for constructing an Arcuate Common Vertex Spring Damper System, that can either be used as a single spring for a torsional vibration application or be used in pairs as a Dual Arcuate Common Vertex Spring Dampers System. Both these constructions yield significant improvements over the conventional Common Vertex and Dual Common Vertex seen in prior art, such as promoting a radially tighter packaging envelop, allowing the resulting device to be tuned across a greater torsional frequency range, and improving the modal decoupling response of the resulting device.

A torsional damper assembly includes a hub having an outer periphery, an annular elastomeric element disposed about the outer periphery, and an annular inertia ring disposed about the elastomeric element. The inertia ring has an inner periphery adjacent the elastomeric element. The outer periphery of the hub is provided with a first plurality of surface features and the inner periphery of the inertia ring is provided with a second plurality of surface features. The first plurality of surface features is complementary to and engaged with the second plurality of surface features.

A dynamic damper includes a resilient material, an annular mass and a metallic split ring. The resilient material has a central bore formed therethrough dimensioned to receive a vehicle axle. The central bore defines a first inner diameter. The annular mass is surrounded and embedded in the resilient material. The annular mass defines a second inner diameter greater than the first inner diameter. The metallic split ring is embedded within the resilient material along a portion of the surface of the central bore with locking protrusions extending into the central bore. Ends of the locking protrusions define a third inner diameter smaller than the first inner diameter. The locking protrusions is dimensioned to extend into openings in the vehicle axle locking the metallic split ring, the resilient ring and the annular mass to the vehicle axle.

The disclosed invention is a novel method for constructing a Torsional Vibration Damper (TVD). The traditional means used to construct the hub of the TVD was to employ a single material. The disclosed invention essentially discretizes the construction of the TVD hub into three regions: nose, spokes, and flange, and simultaneously aligns unique materials and manufacturing methods for each region with the structural loads borne thereby. Consequently, the invention helps in reduces four unwanted characteristics: (1) mass; (2) polar mass moment of inertia; and (3) casting scrap; and (4) cost. Furthermore, because of this construction other enhancements to the axial and angular structural integrity of the TVD can be reaped in certain cases.