An elastomer bearing includes a support block, a carrier, a bearing element, a stop damper, and an elastomer body. The bearing element is attached to the support block. The elastomer body connects the carrier to the bearing element. The support block and the carrier, as viewed in an axial direction of the bearing element, engage with one another with play. The stop damper is arranged in the region of the interface between the support block and the carrier. The stop damper limits a maximum displacement of the support block and the carrier, relative to one another both in a radial direction and in an axial direction.

A vehicle body damper brace including: a rod member having an elongated shape; a housing including a tubular part arranged externally about the rod member; an elastic connector including a first connection body comprising a viscoelastic material, the elastic connector elastically connecting the rod member and the housing to each other in an axis-perpendicular direction; and a regulator provided on at least one axial side of the first connection body and separately from the elastic connector, the regulator suppressing an amount of relative displacement between the rod member and the housing in a prizing direction.

A vehicle body damper brace including: a rod member having an elongated shape; a housing including a tubular part arranged externally about the rod member; an elastic connector including a first connection body comprising a viscoelastic material, the elastic connector elastically connecting the rod member and the housing to each other in an axis-perpendicular direction; and a regulator provided on at least one axial side of the first connection body and separately from the elastic connector, the regulator suppressing an amount of relative displacement between the rod member and the housing in a prizing direction.

The present disclosure provides a mount (1) for mounting an instrument to a movable platform. The mount comprises a base part (11), attachable to the platform, an instrument part (12), to which the instrument is attachable, and a spring and damper arrangement (14, 15) operable between the base part (11) and the instrument part (12) to allow the instrument part (12) to move relative to the base part (11). The mount further comprises first and second lever sets (13, 13a, 13b, 13c), each lever set comprising at least two parallel and spaced apart levers (131), which are rigidly connected to each other and which are pivotably connected to one of the base part (11) and the instrument part (12). The lever sets (13, 13a, 13b, 13c) are pivotable about respective first and second geometric axes, which are non-parallel with each other. The lever sets are pivotable about a respective proximal portion (131p) of the lever (131). A distal portion (131d) of each of the levers (131) is connected to the other one of the base part and the instrument part by a respective elongate flexible member (14) presenting internal hysteresis. The disclosure also provides a movable platform comprising such mount and use of such mount for mounting an instrument to a movable platform.

The present disclosure provides a mount (1) for mounting an instrument to a movable platform. The mount comprises a base part (11), attachable to the platform, an instrument part (12), to which the instrument is attachable, and a spring and damper arrangement (14, 15) operable between the base part (11) and the instrument part (12) to allow the instrument part (12) to move relative to the base part (11). The mount further comprises first and second lever sets (13, 13a, 13b, 13c), each lever set comprising at least two parallel and spaced apart levers (131), which are rigidly connected to each other and which are pivotably connected to one of the base part (11) and the instrument part (12). The lever sets (13, 13a, 13b, 13c) are pivotable about respective first and second geometric axes, which are non-parallel with each other. The lever sets are pivotable about a respective proximal portion (131p) of the lever (131). A distal portion (131d) of each of the levers (131) is connected to the other one of the base part and the instrument part by a respective elongate flexible member (14) presenting internal hysteresis. The disclosure also provides a movable platform comprising such mount and use of such mount for mounting an instrument to a movable platform.

A vehicle body damper brace including: a rod member having an elongated shape; a housing including a tubular part arranged externally about the rod member; an elastic connector including a first connection body comprising a viscoelastic material, the elastic connector elastically connecting the rod member and the housing to each other in an axis-perpendicular direction; and a regulator provided on at least one axial side of the first connection body and separately from the elastic connector, the regulator suppressing an amount of relative displacement between the rod member and the housing in a prizing direction.

A vehicle body damper brace including: a rod member having an elongated shape; a housing including a tubular part arranged externally about the rod member; an elastic connector including a first connection body comprising a viscoelastic material, the elastic connector elastically connecting the rod member and the housing to each other in an axis-perpendicular direction; and a regulator provided on at least one axial side of the first connection body and separately from the elastic connector, the regulator suppressing an amount of relative displacement between the rod member and the housing in a prizing direction.

Provided is a treadmill. The treadmill includes a shock absorbing portion configured to absorb a shock applied to a deck. The shock absorbing portion includes a second anti-vibration rubber portion having a third surface fixed to a frame and a fourth surface fixed to the deck. The third and fourth surfaces are perpendicular to a plate surface direction of the deck. The second anti-vibration rubber portion includes a first anti-vibration sub-rubber having the third surface, a second anti-vibration sub-rubber having the fourth surface, and a plate located between the first anti-vibration sub-rubber and the second anti-vibration sub-rubber. The plate located between the first anti-vibration sub-rubber and the second anti-vibration sub-rubber has a greater hardness than the first and second anti-vibration sub-rubbers.

Provided is a treadmill. The treadmill includes a shock absorbing portion configured to absorb a shock applied to a deck. The shock absorbing portion includes a second anti-vibration rubber portion having a third surface fixed to a frame and a fourth surface fixed to the deck. The third and fourth surfaces are perpendicular to a plate surface direction of the deck. The second anti-vibration rubber portion includes a first anti-vibration sub-rubber having the third surface, a second anti-vibration sub-rubber having the fourth surface, and a plate located between the first anti-vibration sub-rubber and the second anti-vibration sub-rubber. The plate located between the first anti-vibration sub-rubber and the second anti-vibration sub-rubber has a greater hardness than the first and second anti-vibration sub-rubbers.

A anti-vibration device (1) includes a bracket (4) made of a synthetic resin and cylindrical metal fittings for fastening (5), where the bracket (4) and the metal fittings for fastening (5) are integrally formed. A vibration input position (P) is a position that does not coincide with a virtual line (L1) passing through central axes (O5) of a through holes (5h) of two metal fittings for fastening (5) in a planar view; the metal fitting for fastening (5) has a flange portion (51); and the flange portion 51 has a first outermost peripheral edge (51a) and a second outermost peripheral edge (51b), where a length (L51a) to the first outermost peripheral edge (51a) is longer than a length (L51b) to the second outermost peripheral edge (51b) based on the center axis (O5) of the through hole (5h).