An apparatus which damps oscillation in a ski, the apparatus comprising an enclosure, a cavity encompassed by the enclosure, and an aggregate located in the cavity. The cavity has a dimension in a direction perpendicular to a gliding surface of the ski which is larger than a thickness of the ski in a location adjacent to the enclosure. The aggregate, in its tapped density, occupies substantially less volume than a volume of the cavity, thereby allowing significant travel of the aggregate in the cavity. Oscillation accelerates and decelerates the enclosure, resulting in accelerations and decelerations of the aggregate which cause it to acquire and lose kinetic energy. The aggregate's acquisition and loss of kinetic energy attenuates the oscillation.

A damper includes a damper body that is configured to be attached to a workpiece during a machining process. A first side of the damper body is configured to abut a first side of the workpiece. The damper body includes a frame forming an outer periphery of the damper body, a plurality of damper nodes with a cavity in each damper node positioned in the frame, and a plurality of ribs extending between the frame and the damper nodes. A damping material is positioned in the cavity of each damper node.

Disclosed are devices and methods for reducing resonant vibrations in impact tools. The embodiments disclosed herein include the use of certain particles positioned within an impact tool, such as a hammer, for converting the energy of vibration to heat energy resulting from collisions between the particles.

A system for mitigating vibration of a mass may include an elastic membrane enclosing at least one interior space and having an outer surface, where at least a bottom portion of the outer surface is coupled to a transportable supportive surface, and at least a top portion of the outer surface supports a load. The system may further include at least one port coupling the outer surface to the at least one interior space, where the port provides a source of fluid ingress into the interior space and fluid egress out of the interior space. The system may additionally include granular material distributed within the at least one interior space, where a packing density of the granular material is adjustable between a first jammed state having a first packing density of granular materials and a second jammed state having a second packing density of granular materials to accommodate different loads.

Disclosed are devices and methods for reducing resonant vibrations in impact tools. The embodiments disclosed herein include the use of certain particles positioned within an impact tool, such as a drumstick, for converting the energy of vibration to heat energy resulting from collisions between the particles.

A system for mitigating vibration of a mass may include an elastic membrane enclosing at least one interior space and having an outer surface, where at least a bottom portion of the outer surface is coupled to a transportable supportive surface, and at least a top portion of the outer surface supports a load. The system may further include at least one port coupling the outer surface to the at least one interior space, where the port provides a source of fluid ingress into the interior space and fluid egress out of the interior space. The system may additionally include granular material distributed within the at least one interior space, where a packing density of the granular material is adjustable between a first jammed state having a first packing density of granular materials and a second jammed state having a second packing density of granular materials to accommodate different loads.

A passive vibration damper for damping vibrations, particularly for damping vibrations of a printed circuit board, includes a chamber having a surrounding wall which defines a cavity. The volume of the cavity is at least 2% of the volume of the vibration absorber and not more than 95% of the volume of the vibration absorber. The chamber includes particles, wherein the wall and the particles have the same material composition.

A toolholder includes a cutting tool mounted to a head attached to a collar at a first end of the toolholder. A shank is located at a second, opposite end of the toolholder. A central cavity extends inwardly from the first end toward the shank. A passive vibration absorber assembly is disposed within the central cavity. The passive vibration absorber assembly includes an absorber body and an absorber cap attached to the absorber body. The absorber body has a first end, a second end opposite the first end, and one or more cavities formed in the second end. The one or more cavities of the absorber body are partially of wholly filled with metal or ceramic particles or powders to provide particle damping for suppressing vibration of the toolholder.

A system for mitigating vibration of a mass may include an elastic membrane enclosing at least one interior space and having an outer surface, where at least a bottom portion of the outer surface is coupled to a transportable supportive surface, and at least a top portion of the outer surface supports a load. The system may further include at least one port coupling the outer surface to the at least one interior space, where the port provides a source of fluid ingress into the interior space and fluid egress out of the interior space. The system may additionally include granular material distributed within the at least one interior space, where a packing density of the granular material is adjustable between a first jammed state having a first packing density of granular materials and a second jammed state having a second packing density of granular materials to accommodate different loads.

A device for suppressing low-frequency line spectrum vibration includes a main housing, a diaphragm assembly having an upper diaphragm and a lower diaphragm, and a particle damper arranged in the main housing. Two ends of the main housing are respectively provided with an upper end cover and a lower end cover. The upper diaphragm and the lower diaphragm are respectively installed at the two ends of the main housing through the upper end cover and the lower end cover; and a particle damper. Two ends of the particle damper are respectively connected to the upper diaphragm and the lower diaphragm, and the upper diaphragm and the lower diaphragm are used for transmitting external vibration energy into the particle damper, and the particle damper is used for dissipating vibration energy.