A vibration damping mount is disclosed that is designed to be mounted to a vehicle such as a car, truck, ATV or boat and accommodate an electronic device with a screen. The vibration damping mount may be mounted by a bracket, bolts, a clamp, or other coupling means. The vehicle-mounted portion and device-mounting portion of the vibration damping mount may generally be connected by a piston having springs on either side to absorb vibrational energy from the motion of the vehicle the system is mounted to, thereby reducing vibration of the screen of any electronic device mounted to the system. The springs may be further tuned by tightening or loosening tuning screws in contact with the springs, thereby increasing or decreasing the force of the springs on the piston. This allows the vibration damping mount to be adapted to a variety of vehicles and circumstances.

A pivot unit comprising a linear actuator; a rod assembly driven by the linear actuator; an output shaft driven by the rod assembly; a housing enclosing the rod assembly and a portion of the output shaft, and attached to the linear actuator; a saddle driven by the output shaft; a first stop arm operatively attached to the first arm and a first end of the output shaft; a second stop arm operatively attached to the second arm and a second end of the output shaft; a first shock absorber secured to a first side of the housing and constructed and arranged to accept a first end of the first stop arm; and a second shock absorber secured to a second side of the housing and constructed and arranged to accept a first end of the second stop arm.

Proposed is an anti-vibration mount using combination of multiple springs in which a main spring is provided between an upper frame and a lower frame to reduce vibration, and an auxiliary spring is provided at each of the side portions of the upper frame such that the direction and magnitude of a force applied by the auxiliary spring change according to the compressed degree of the main spring, so the effect of an air spring is realized only with the combination of the main and auxiliary springs which are coil springs. The anti-vibration mount includes: the upper frame allowing an object to be installed thereon; the lower frame provided under the upper frame by being spaced apart therefrom; the main spring provided between the upper frame and the lower frame; and the auxiliary spring elastically supporting each of opposite sides of the upper frame and the lower frame.

A contact bounce reduction system including: a movable member, and a contact bounce damping device including: a body, a first ball and a second ball, a first resilient member and a second resilient member, a piston. The first resilient member holds the first ball in the seat and the second resilient member holds the second ball in the seat when the piston is in a default extended position, and a third resilient member biases the piston towards the default extended position. The movable member actuates the piston towards the retracted position, causing the first ball and the second ball to move radially out from the seat, and the third resilient member to accumulate energy.

A seismic isolator is provided, which is excellent in vertical shock-absorbing and vibration reducing, has more functions of horizontal shock-absorbing, recovering, and reaction-force resisting, is easy to install while adjusting the horizontal level of supporting structure in the construction site, and is able to adjust the height of the supporting structure even after installed in the construction site. The seismic isolator includes a wedge unit including a rod, a pair of wedges installed movably along the rod, a horizontal elastic body engaging the rod and supporting the pair of wedges and a supporting means supporting the horizontal elastic body, a wedge bottom surface member supporting the pair of wedges while surface-contacting a wedge bottom surface of the wedge surface of the pair of wedges, and a wedge top surface member supported by the pair of wedges while surface-contacting a wedge top surface of the wedge surface of the pair of wedges.

A seismic isolator is provided, which is excellent in vertical shock-absorbing and vibration reducing, has more functions of horizontal shock-absorbing, recovering, and reaction-force resisting, is easy to install while adjusting the horizontal level of supporting structure in the construction site, and is able to adjust the height of the supporting structure even after installed in the construction site. The seismic isolator includes a wedge unit including a rod, a pair of wedges installed movably along the rod, a horizontal elastic body engaging the rod and supporting the pair of wedges and a supporting means supporting the horizontal elastic body, a wedge bottom surface member supporting the pair of wedges while surface-contacting a wedge bottom surface of the wedge surface of the pair of wedges, and a wedge top surface member supported by the pair of wedges while surface-contacting a wedge top surface of the wedge surface of the pair of wedges.

A step-down spring seat assembly secured to a vibratory screen machine is configured to receive one or more universal adapter plate assemblies, to which one or more compression springs is secured. The universal adapter plate assemblies are secured to a top surface of the step-down spring seat assembly, and one or more spring guide castings are connected to the one or more universal adapter plate assemblies. Compression springs are positioned atop the spring guide castings, and are secured to a top adapter plate assembly that is connected to one or more universal adapter plate assemblies positioned above the one or more compression springs.

A shock-resisting device includes a snubber that may be selectively moved from a retracted position to an engaged position to selectively create a stiff attachment between a vibration-isolated gimbal of the device, and an outer shell of the device. The gimbal is movable relative to the outer shell. The snubber includes a retainer maintaining the snubber in the retracted position, wherein the snubber is configured to move from the retracted position to the engaged position in response to loss of power to the retainer.

A shock-resisting device includes a snubber that may be selectively moved from a retracted position to an engaged position to selectively create a stiff attachment between a vibration-isolated gimbal of the device, and an outer shell of the device. The gimbal is movable relative to the outer shell. The snubber includes a retainer maintaining the snubber in the retracted position, wherein the snubber is configured to move from the retracted position to the engaged position in response to loss of power to the retainer.

A front fork leg includes an inner chamber that absorbs by a gas spring a shock caused on a vehicle; an auxiliary gas spring chamber communicating with the inner chamber; an auxiliary piston provided in the auxiliary gas spring chamber; and a gas spring chamber side gas chamber sectioned by the auxiliary piston and communicating with the inner chamber, and the auxiliary piston moves to increase a volume of the gas spring chamber side gas chamber, as pressure inside the inner chamber increases.