A vibration-damping device (10) includes a first attachment member (11), a second attachment member (12), an elastic body, and a partitioning member (16). A limiting passage (30) that allows a main liquid chamber (14) and an auxiliary liquid chamber (15) to communicate with each other is formed in the partitioning member (16). An inner peripheral surface of the limiting passage (30) is provided with a flow changing protrusion (31) that protrudes toward an inner side in a radial direction of the limiting passage (30) and that changes the flow of a liquid (L) that flows into the limiting passage (30) from the main liquid chamber (14) and flows through the limiting passage (30) in an axial direction of the limiting passage (30). In a vertical cross-sectional view passing through an axis of the limiting passage (30) and through the flow changing protrusion (31), the limiting passage (30) and the flow changing protrusion (31) have symmetrical shapes with respect to the axis. A protruding end of the flow changing protrusion (31) forms an inner peripheral edge of a passage hole (31c) that is open on both sides in the axial direction.

A restraint system includes a housing, a spool rotatably coupled to the housing, a pinion fixed to the spool, a rack engaged with the pinion, and a piston attached to the rack and the housing. The piston is filled with a resilient material. The resilient material may be a heterogeneous mixture of a liquid and hydrophobic, nanoporous particles.

A torsional vibration damper or torsional vibration absorber has a rotating system with: a primary mass, which is arranged on a rotatable shaft, for example on a crankshaft of an engine, in particular of an internal combustion engine, and preferably can be fastened for conjoint rotation; a secondary mass, which is movable relative to the primary mass; and an assembly for vibration damping and/or vibration absorption of the relative movement between the primary mass and the secondary mass. The assembly for vibration damping and/or vibration absorption of the relative movement between the primary mass and the secondary mass has at least one accumulator inside the rotating system of the torsional vibration damper or torsional vibration absorber.

A resilient expandable pressure vessel configured to function like a spring. The resilient expandable pressure vessel includes a body portion, a cavity defined within the body portion, and at least one port in communication with the cavity defined in the body portion. The at least one port is configured to receive a fluid into the cavity and discharge the fluid from the cavity. The resilient expandable pressure vessel has a predetermined expansibility across a range of operating pressures of the fluid in the cavity. The range is at least 200 psi.

When an insulator is of non-circular shape, a spring ratio of an X direction to a Y direction is increased by utilizing this non-circular shape. A pair of direction elastic walls opposed to each other in the X direction is formed short and thin in the Y direction and has a small X direction projected area. Similarly, a second mounting metal fitting is formed in a rectangular shape extending long in the X direction and includes a pair of X direction restraint walls opposed to each other in the X direction and a pair of Y direction restraint walls opposed to each other in the Y direction. A first mounting metal fitting includes a pair of X direction restraint projecting parts opposed to each other in the X direction and a pair of Y direction restraint walls opposed to each other in the Y direction.

The present subject matter relates to improved damping fluid mount devices, systems, and methods in which a damping fluid mount (100) includes an inner member (110), an elastomer section (130) that is affixed to an outer surface of the inner member (110), and a cup (200) containing viscous fluid (300). The elastomer section (130) has an outer diameter that is variable along an elastomer contour, and a crimped portion of the cup is radially crimped into the elastomer section (130) such that the crimped portion precompresses the elastomer section (130) and substantially mimics the elastomer contour.

A vibration isolator (10) includes a first attachment member (11), a second attachment member (12), an elastic body (13), and a partition member (16) configured to partition a liquid chamber in the first attachment member in which a liquid (L) is sealed into a first liquid chamber (14) and a second liquid chamber (15). A communicating passage (30) configured to communicate the first liquid chamber with the second liquid chamber is provided in the partition member. A flow changing protrusion (31) is provided at an inner circumferential surface (30a) of the communicating passage. A guide surface (32) opposite to the communicating passage and intersecting the axial direction (O) of the communicating passage is provided at the flow changing protrusion. A passing hole (34) which is open toward both sides in the axial direction is formed by a projecting end (31b) of the flow changing protrusion and another place on the inner circumferential surface (30b) of the communicating passage. The flow changing protrusion changes the flow of the liquid flowing in the communicating passage and reaching the guide surface toward the projecting end. The guide surface is formed in a concave curved surface shape which is recessed in the axial direction.

An engine mount is provided in which a nozzle plate is mounted between an insulator and a diaphragm to divide an inner space into an upper liquid chamber and a lower liquid chamber. A hydraulic liquid flows between the upper and lower liquid chambers through a first flow path formed on the nozzle plate based on a change in volume in the engine mount. The nozzle plate which includes a second flow path having an outlet disposed at an upper end of the second flow path and in communication with the upper liquid chamber. A diaphragm is coupled to a lower portion of the nozzle plate to form the lower liquid chamber, and divides the lower liquid chamber into a main liquid chamber and an auxiliary liquid chamber. Additionally, a valve plate is seated at an upper side of the upper end of the second flow path.

A floor portion (34) is formed to be inflected to a radial direction inner side from a lower end portion of a channel outer tube portion (32), and is disposed apart from and opposing a flange portion (24) at an outer periphery side of a tube portion (22) of a dividing member (20). The floor portion (34) is disposed within the tube portion (22) in an axial direction S, that is, so as to overlap with the tube portion (22) when viewed from a radial direction. A diaphragm (50) in the form of an elastic film is adhered by vulcanization to a restriction channel member (30) so as to cover an aperture in a lower side of the restriction channel member (30). A seal portion (56) is vulcanization-formed integrally with the diaphragm (50), so as to cover an inner periphery face of a channel inner tube portion (36) of the restriction channel member (30).

A vibration isolator of the present invention includes a first attachment member (11), a second attachment member (12), an elastic body (13), a partition member (15), and a movable member (23). In addition, a plurality of communicating holes (27a and 27b) extending outward in an axial direction from a portion facing the movable member (23) in the axial direction in a wall surface of an accommodating chamber (18) and configured to communicate the accommodating chamber (18) with a main liquid chamber (16a) or a subsidiary liquid chamber (16b) are provided in the partition member (15), at least one of the plurality of communicating holes (27a and 27b) is a direct coupling hole (27a) configured to directly couple the accommodating chamber (18) with the main liquid chamber (16a) or the subsidiary liquid chamber (16b) in the axial direction, a flow control member (30) positioned at an outside in the axial direction relative to the direct coupling hole (27a) and disposed to overlap the movable member (23) in the axial direction through the direct coupling hole (27a) is further provided, and the flow control member (30) does not come into contact with the movable member (23) deformed in the axial direction when a liquid pressure of the main liquid chamber (16a) varies based on an input from a vibration-generating part.