The present invention relates to a vibration damping device including an outer attachment member (10) connected to one of a vibration generating part and a vibration receiving part, an inner attachment member (20) connected to the other, and an elastic body (30) configured to connect the outer attachment member (10) and the inner attachment member (20), wherein the outer attachment member (10) is formed in a cylindrical shape, the inner attachment member (20) includes a plate-shaped rigid member (21) disposed in the outer attachment member (10) and an interior member (28) located in the outer attachment member (10), fixed to the rigid member (21), and formed of a synthetic resin material, and, at protruding portions (22, 23) of the rigid member (21) which protrude outward from the outer attachment member (10) in an axial direction along a central axis (O) of the outer attachment member (10), mounting holes (22a, 23a) which are open in a diameter direction orthogonal to the axial direction and have a fastening member configured to connect the protruding portions (22, 23) and the other of the vibration generating part and the vibration receiving part fitted thereinto are formed.

A tubular vibration-damping device having a bracket including a tubular vibration-damping device press-fitted and attached into a tubular bracket, the tubular vibration-damping device including an inner shaft member, an outer tube member made of synthetic resin and disposed on an outer peripheral side of the inner shaft member, and a main rubber elastic body connecting the inner shaft member and the outer tube member. An inside projection is integrally formed with the outer tube member so as to project radially inwardly. A gap is provided between an outer peripheral surface of the outer tube member and an inner peripheral surface of the tubular bracket at a position in a peripheral wall part of the outer tube member where the inside projection is formed.

A spring element includes a longitudinal axis, a main body that extends along the longitudinal axis and which can be elastically deformed between an uncompressed base state and a state in which the main body is compressed in the direction of the longitudinal axis, a groove extending peripherally on the outside of the main body, and a supporting ring arranged in the groove. A plurality of cut-outs is formed between the supporting ring and the main body in the groove in the base state of the main body. A vehicle shock absorber and a vehicle can use the spring element.

A spring element includes a longitudinal axis, a main body that extends along the longitudinal axis and which can be elastically deformed between an uncompressed base state and a state in which the main body is compressed in the direction of the longitudinal axis, a groove extending peripherally on the outside of the main body, and a supporting ring arranged in the groove. A plurality of cut-outs is formed between the supporting ring and the main body in the groove in the base state of the main body. A vehicle shock absorber and a vehicle can use the spring element.

The present disclosure includes independent suspension systems or members, as well as wheeled skid steer loaders or other power machines including the same, that couple each wheel to a machine frame using a four-bar linkage, with the four bars including the frame of the machine, an upper control arm, a lower control arm, and a wheel carrier link. Each control arm is pivotally attached to both the machine frame and one end of the wheel carrier link. The four pivots between the control arms and the wheel carrier link are configured to all be contained within cylinder defined by the outer diameter of the wheel rim, allowing for a compact structure with the wheel carrier link and at least part of the control arms being positioned within this volume when the loader is in a resting position.

An energy management jounce bumper assembly absorbs energy between a first component and a second component of a vehicle. The energy management jounce bumper assembly includes a bumper axially compressible between the first and second components. A plate is connected to the bumper. The plate has a body portion having a first surface and a second surface opposite the first surface. A first plurality of ribs is disposed on the first surface and a second plurality of ribs is disposed on the second surface. The body portion of the plate has a standard position wherein the body portion is either one of planar and non-planar and has a first height. The plate is adaptable between the standard position and a compressed position wherein the body portion is either one of non-planar and planar, respectively, and has a second height that is less than the first height.

An energy management jounce bumper assembly absorbs energy between a first component and a second component of a vehicle. The energy management jounce bumper assembly includes a bumper axially compressible between the first and second components. A plate is connected to the bumper. The plate has a body portion having a first surface and a second surface opposite the first surface. A first plurality of ribs is disposed on the first surface and a second plurality of ribs is disposed on the second surface. The body portion of the plate has a standard position wherein the body portion is either one of planar and non-planar and has a first height. The plate is adaptable between the standard position and a compressed position wherein the body portion is either one of non-planar and planar, respectively, and has a second height that is less than the first height.

A spring element for a vehicle shock absorber. The spring element includes a longitudinal axis and a basic body that extends along the longitudinal axis and is deformable resiliently between an uncompressed basic state and a state compressed in the direction of a longitudinal axis, and which includes an end side with a stop surface configured for contact against a damper cap of the vehicle shock absorber. The stop surface is at least partially structured. A passenger motor vehicle car can include such a spring element.

A spring element for a vehicle shock absorber. The spring element includes a longitudinal axis and a basic body that extends along the longitudinal axis and is deformable resiliently between an uncompressed basic state and a state compressed in the direction of a longitudinal axis, and which includes an end side with a stop surface configured for contact against a damper cap of the vehicle shock absorber. The stop surface is at least partially structured. A passenger motor vehicle car can include such a spring element.

The present invention is to provide a bound stopper, which has high mechanical strength, is excellent in durability against fatigue breaking, settling or the like when a heavy load is repeatedly received, and is easy to be produced, in which the bound stopper comprises a polyurethane foam obtained from a polyurethane foam composition containing an isocyanate component and a blowing agent, and the isocyanate component contains a urethane prepolymer having an isocyanate group, the urethane prepolymer being obtained from a polyol component, a polyrotaxane containing a cyclic molecule having an active hydrogen group as a constituent, and an isocyanate.