A roll-rod for a vehicle which is mounted so as to connect a sub-frame and a power train may include at least one rubber block mounted between a front body portion and a rear end plate, in which the rubber block disposed at a rearmost part may be formed with a U-shaped band portion having an opening to which the end plate is fitted and joined wherein the U-shaped band portion is open in a vertical direction to the axial direction of a rearmost rubber block of the at least one rubber block to form the opening.

A roll mount is provided and includes a rubber coupled to a core mounted in an exterior pipe coupled to an end of a main body, slits that are formed in the rubber at the periphery of the core, and a pocket that is disposed within the slits. The pocket includes a first pocket portion having a first and second chamber formed therein and connecting portions having flow paths that connect the first and second pocket portion and place the first and second chamber in fluid communication. A magnetorheological fluid is encapsulated in the first and second chamber, and flows therethrough, via the flow paths based on elastic deformation of the first and second pocket portion. The wound coils are disposed at exterior sides of the first and second pocket portions, and fluidity of the magnetorheological fluid is adjusted based on the electric current applied to the coil.

A split bushing torque strut isolator assembly for a vehicle is provided. The assembly includes a lower bushing configured to be disposed in a vehicle structural component, a bushing housing configured to be coupled to the vehicle structural component, an upper bushing disposed at least partially within the bushing housing, the upper bushing being separate from the lower bushing, and a torque rod having a first end and a second end, the second end being disposed between the upper and lower bushings. A method of assembling the split bushing torque strut isolator assembly is also provided.

A vibration dampening engine mount configured to mount an engine to a vehicle frame includes: a first bolt receiver having a first through hole configured to receive a first bolt; a second bolt receiver having a second through hole configured to receive a second bolt; and a mass damper connector integrally connecting the first bolt receiver and the second bolt receiver, wherein the vibration dampening engine mount has a predetermined mass.

A roll restrictor for restraining movement of a vehicle powertrain relative to a vehicle sub-frame. The roll restrictor has a bracket for coupling to the sub-frame in the form of a generally U-shaped housing defining a central cavity. A link arm for coupling to the powertrain has a first end positioned within the cavity and extends through an opening in the bracket. A plurality of resilient elements are disposed within the cavity between the housing and the first end of the link arm to resist movement of the first end relative to the bracket.

A powertrain housing assembly (200) for a vehicle powertrain has a powertrain housing (210) configured to house at least a portion of the vehicle powertrain (10). A mount (230) is configured to directly receive a torque roll restrictor (120) for attaching the powertrain housing to a vehicle sub-frame, wherein the mount is integral with the powertrain housing and the mount is configured to movably receive the torque roll restrictor such that the torque roll restrictor is movable relative to the mount during use.

The invention relates to a link element (1) for a motor vehicle, comprising a connecting rod (2) and a coupling element (3) for coupling the connecting rod (2) to a subassembly of the motor vehicle, wherein the coupling element (3) comprises a housing (5) with a passage (6) through which the connecting rod (2) extends into the housing (5); characterized by a stop plate (7) for supporting forces transferred to the coupling element (3) by the connecting rod (2).

A torque rod (1) has two elastic bushes (2, 3) to be mounted respectively to a vibration-generating side and a vibration-receiving side, and a connecting rod (4) connecting the two elastic bushes (2, 3). The actively controlled vibration cancellation means (5) is an actuator including: the shaft (5a) having two opposite ends mounted to the connecting rod (4) and extending in an axial direction of the connecting rod (4), the mass member (5b) shaped in a tube to surround the shaft (5a); a coil (5e) and a winding core (5f) fixed to the shaft (5a) in the tube-shaped mass member (5b); a permanent magnet (5d) mounted to an inner peripheral surface of the tube-shaped mass member (5b) or the shaft (5a), and a connecting member (5c) for connecting at least one end of the tube-shaped mass members (5b) to the shaft (5a).

An engine mount for a drive unit in a vehicle includes a bracket having first and second joining points for attachment of the bracket to the drive unit. A first mounting member connects the bracket to the drive unit in the first joining point along a first joining axis. An engine mount is arranged on a vehicle body and supports the drive unit via the bracket. A second mounting member connects the bracket to the drive unit in the second joining point along a second joining axis. The first and second joining axes extend at a slant to each other by an axis angle.

A roll mount is provided and includes a rubber coupled to a core mounted in an exterior pipe coupled to an end of a main body, slits that are formed in the rubber at the periphery of the core, and a pocket that is disposed within the slits. The pocket includes a first pocket portion having a first and second chamber formed therein and connecting portions having flow paths that connect the first and second pocket portion and place the first and second chamber in fluid communication. A magnetorheological fluid is encapsulated in the first and second chamber, and flows therethrough, via the flow paths based on elastic deformation of the first and second pocket portion. The wound coils are disposed at exterior sides of the first and second pocket portions, and fluidity of the magnetorheological fluid is adjusted based on the electric current applied to the coil.