A fluid-filled vibration damping device including an inner member, an outer member having a tubular part, a main rubber elastic body elastically connecting the two members, and a partition disposed on a radially inner side of the tubular part. An axial end portion of the main rubber elastic body is anchored to a radially inner surface of the tubular part and includes a sealing rubber. The partition includes a press-sealing face positioned at an outer peripheral edge of an axial end face thereof, and is pressed against an axial end face of the sealing rubber at the press-sealing face. A seal rib protruding axially outward from the press-sealing face of the partition is more strongly pressed against the axial end face of the sealing rubber such that a fluid-tight sealing is provided axially between the sealing rubber and the partition.

A transmission mount for a vehicle is capable of being press-fitted to a vehicle body side member with only an insulator, and without use of a bridge bracket, such that reduction in weight and cost can be achieved by eliminating the bridge bracket, and assembly workability can be improved by eliminating a bolting operation.

In an anti-vibration apparatus having a bracket where an anti-vibration apparatus body in which a first mounting member and the second mounting member are connected by a body rubber elastic body is horizontally mounted to the bracket by fitting parts disposed on two sides of a width direction of the second mounting member in the anti-vibration apparatus body to fitting grooves disposed on opposite inner surfaces on two sides of a width direction of the bracket, a locking hole is provided on a deep wall part located on a deep side in a mounting direction of the second mounting member in the bracket, and a locking part is disposed at a tip portion in the mounting direction of the second mounting member to the bracket, and prevents return in a direction opposite to the mounting direction by inserting and locking the locking part to the locking hole.

The invention relates to an arrangement for the drive mounting, in particular for a motor vehicle, preferentially a utility vehicle. The arrangement comprises a supporting structure, in particular a cross member structure. The arrangement comprises an, in particular electric, drive unit, which is attached to the supporting structure in a 3-point mounting on an underside and/or from below. Advantageously, the drive unit can thus be fed to the motor vehicle from the rear end. The drive unit can be practically lifted in order to be then attached to the supporting structure on an underside or from below. The 3-point mounting makes possible a quick assembly. In addition, a static redundancy of the mounting through too many bearing points (e.g. four or more) is prevented.

A torque rod 16 which supports a driving source 11 on a vehicle body 15 includes: an annular first end part 17 which is connected to the driving source 11 while holding a first elastic bush 21 in an inner circumference thereof; an annular second end part 18 which is connected to the vehicle body 15 while holding a second elastic bush 23 in an inner circumference thereof; and a rod-shaped coupling part 19 which couples the first end part 17 and the second end part 18 to each other. An outer circumferential face of the first end part 17 includes a projection part 17a which projects radially outward so as to extend away from the second end part 18, and a mounting part 17b to mount a mass body 26 is formed in the projection part 17a.

An antivibration unit attachment structure according to the present aspect includes: a vibration absorption part having a first elastic member which is elastically deformable in a first direction and which is connected to a vibration generation part; and a second elastic member which supports the vibration absorption part and which is connected to a vibration reception part. The second elastic member includes a movable part that extends from the vibration absorption part to both sides in a second direction and that is supported by the vibration reception part. The second elastic member is elastically deformable in the first direction and has an elastic coefficient different from that of the first elastic member. The vibration reception part includes a regulation member that comes into contact with at least one of the vibration absorption part and the second elastic member and that limits displacement of the second elastic member to the first direction.

A transmission-side mount bracket includes connection portions which connect a front-side leg portion and a rear-side leg portion of a leg member, a middle attachment (fixation) portion which is provided at the connection portions at a position located between the front-side leg portion and the rear-side leg portion and fixed to the powertrain, and a rigidity-reduction portion (an opening portion) which has the rigidity against a load applied in the vehicle width direction which is lower than that of the front-side leg portion and the rear-side leg portion and is provided at a position located in the vicinity of the middle attachment (fixation) portion.

Provided is a vibration damping device that reduces parts cost and improves productivity. The vibration damping device includes: a mounting member (10) that is attached to a vibration source; a holder (20) that is attached to a vibration receiver; and an insulator (30) that connects the mounting member (10) with the holder (20), wherein the holder (20) has a base portion (21) to which an end of the insulator (30) is coupled and a stopper portion (22) that rises from the base portion (21), and the insulator (30) has a pair of rubber feet (31 a, 31 b) that faces each other at a distance, wherein the pair of rubber feet (31a, 31 b) defines a cavity (35) therebetween, and the base portion (21) has an opening (25) formed therein at a position corresponding to the cavity (35).

A fluid-enclosed engine mount may include an insulator mounted between a core configured to be connected to an engine and an external pipe configured to be connected to a vehicle body, the insulator being provided with an internal space enclosing fluid; an orifice module disposed at the inside of a lower side portion of the insulator to divide the internal space into an upper chamber and a lower chamber, the orifice module being provided with a fluid passage for allowing fluid to fluidically-communicate between the upper chamber and the lower chamber; a support member disposed between an external surface of the orifice module and the lower side portion of the insulator to elastically support the orifice module to be vertically movable; and a pipe member disposed between the lower side portion of the insulator and the support member to support an external surface of the support member.

A fluid-filled vibration damping device including an inner member, an outer member having a tubular part whose radially inner surface has a quadrangular tube shape, a main rubber elastic body elastically connecting the two members, and a partition having a quadrangular plate shape disposed on a radially inner side of the tubular part. An outer peripheral surface of an axial end of the main rubber elastic body is anchored to the radially inner surface of the tubular part. An annular sealing rubber pressed against an outer peripheral edge of an axial end face of the partition is provided to the axial end of the main rubber elastic body. An axis-perpendicular inside dimension and a width dimension of the sealing rubber are made larger in a diagonal direction of the radially inner surface of the tubular part than in an opposite side direction thereof.