Various systems are provided for damping vibration in a mobile radiographic imaging system. In one embodiment, a vibration damping assembly for a C-arm imaging system comprises a pivot element rotatably coupled to a toe portion of the C-arm imaging system and configured to form an interface between the toe portion, a damping element, and a ground surface on which the C-arm imaging system sits.

This invention pertains to hydraulic cylinders or shock absorbers, and a method of controlling the operation and flow of fluid within them. Specifically, this invention relates to use of a coil and valve mounted onto a shock shaft and mounting eyelet absorber or vehicle body) within a shaft and mounting eyelet of a damping assembly that utilizes electronically controlled inputs to regulate operational forces, essentially turning the shaft assembly into a solenoid.

Cylindrical diaphragm assembly of reduced diameter for hydraulic shock absorbers with sealing at both ends, of those used in self-closing furniture, which at its outer end performs the sealing of the cylindrical body of the shock absorber and at its inner end performs the sealing of the shock absorber shaft, said cylindrical diaphragm assembly being on its outer side a fluid compensation chamber and on the other inner side an aerial chamber and consisting of an insertable elastic hood whose inner end has an annular decrease in diameter, generating a flat support area and ending in a conical extension of a simple seal in contact with the axis of the shock absorber, and of an inner tubular centering male provided at its inner end with a conical head with a flat outer wall for support and fixing of said insertable elastic hood; and that said inner tubular centering male has longitudinal flaps, said inner tubular centering male ending in a closure plug prominence which, with the outer end of the insertable elastic hood, generates a simple seal with the cylindrical body of the shock absorber.

The invention relates a method for manufacturing a damper device including a first part and a second part, said method comprising the following steps: a) providing a damping material in a space in between the first part and the second part, such that the damping material is in a compressed state in the space; and b) heating the device to a predetermined temperature in order to adhere the damping material to the first part and the second part.

A torque link assembly for a shock strut includes an upper torque link that is selectively retained in a stowed position when uncoupled from a lower torque link. The upper torque link includes first and second coaxial lugs that rotatably couple the upper torque link to an alignment feature. A latch mechanism includes a latch fitting rotatably coupled to either the upper torque link or the alignment feature. The latch mechanism further includes a stop fitting fixedly coupled to the other of the upper torque link and the alignment feature. The latch fitting engages the stop fitting to maintain the upper torque link in the stowed position. At least one of the latch fitting and stop fitting is positioned between the first and second lugs of the upper torque link.

A metering pin for use in a multi-actor damping system is disclosed herein. The multi-actor damping system may be used in a shock strut assembly to alter a damping curve of the shuck strut assembly. The metering pin may be configured to transition the multi-actor damping system from a first damping actor configuration to a second damping actor configuration. The first damping actor configuration may correspond to a first damping curve. The second damping actor configuration may correspond to a second damping curve. The first damping curve being different than the second damping curve.

The present disclosure discloses a nonlinear spring connection structure and a motor. The nonlinear spring connection structure includes a stator, a mover and an elastic connector provided between the stator and the mover. The elastic connector includes a first end connected with the stator, a second end connected with the mover and at least two transition-connecting portions connected between the first end and the second end. The at least two transition-connecting portions extend from the first end towards the second end with sequentially decreasing sizes. An elastic connector is provided between a stator and a mover. In practice, the elastic connector, through deformation of itself, provides a restoring force for the mover during movement, so that the mover can perform a linear movement relative to the stator. In this way, a nonlinear spring connection structure is simpler and manufacturing cost of the nonlinear spring connection structure is reduced.

A system or structure subject to external mechanical dynamic loading excitations propagated within the system or structure comprising a fluid filled structure and a fluid volume operable to facilitate fluid flow about at least part of the structure. Excitations within the structure can be propagated throughout. The system can further comprise a tuned mass damper (TMD) located within the fluid volume. The TMD can leverage the viscous properties of the fluid to attenuate the excitations within the structure. The TMD can comprise a mass and a spring operably connected to the mass. The TMD can further comprise a fluid resistance facilitating fluid flow about the mass and the spring for damping and a secondary tuning device operably connected to at least one of the mass and the spring and the supporting fluid-filled structure.

A pre-compression type emergency air spring assembly includes an upper cover plate, an air bag, an upper end plate, and a lower end plate. A periphery of the upper end plate is connected with a periphery of the lower end plate through the air bag. A top part of the upper end plate is provided with transverse pre-compression cavities and transverse pre-compression plates arranged at transverse openings of the transverse pre-compression cavities. The transverse pre-compression cavities are internally provided with laminated spring elastomers through the transverse pre-compression plates in a pressing mode. Multiple steel springs are arranged between the upper cover plate and the upper end plate in a pressing mode along a circumferential direction of the laminated spring elastomers. The upper cover plate is arranged on a periphery of the transverse pre-compression cavities in a sleeving mode.

An insert (510) comprising a core (532) and one or more extensions (530) extending from the core. The insert is adapted to be inserted into a cavity of a hollow tube-shaped member (512). The hollow member can be a motorcycle handlebar or footrest. The insert can be made of metal or a polymer and can be an extrusion product.