Abstract: A piston and valve stem assembly is held in either a gate open or gate closed position by a valve gate piston retention device until such time as sufficient air pressure is built up behind the piston, upon which the valve gate piston retention device is signaled to release the piston. The piston, being pre-charged, is thereby able to overcome both static and dynamic friction thus allowing it to move freely and immediately, and in the case of multiple pistons, simultaneously or sequentially, and without hesitation. Both simultaneous or sequential retention and release of the piston via mechanical or electromagnetic means can be controlled to actuate a plurality of pistons forward or back in an expeditious manner to overcome pneumatic losses and frictional forces in an effort to achieve more precise timing of the valve stem and optimize overall cycle time.

Abstract: A system (100, 200, 300) for damping vibrations of a vibratory structure (104, 308). The damping system includes an active damper (112, 124, 128, 216), a vibration sensor (116, 208, 208A?-C?), and a controller (120, 212) for controlling the active damper in a manner that damps vibration of the vibratory structure. In some embodiments, the active damper comprises an active mass (132, 220, 220A?-C?, 220A?-C?) and an actuator (136) for controlling the movement of the active mass. In other embodiments, the active damper comprises a flexural damper (128).

Abstract: A system and method for evaluating the structural integrity of an injection molding machine and/or a component thereof may comprise at least one sensor operatively connected to a component of the injection molding machine. The sensor may transmit a signal representative of the movement of the injection molding machine. A processor may convert this signal into a frequency domain signal and compare it against a frequency template. Changes to the structural integrity of the injection molding machine may result in changes to the system's frequency response spectrum such as, but not limited to, amplification of certain frequency peaks, amplitude variations, changes in the damping characteristics, the shifting of the fundamental mode (i.e., the first natural frequency), shifting of higher order modes (those above the fundamental mode), or the introduction of a new frequency mode of vibration that did not exist prior to the damage of the component.

Abstract: Self-healing cable apparatus and methods are disclosed. The cable has a central core surrounded by an adaptive cover that can extend over the entire length of the cable or just one or more portions of the cable. The adaptive cover includes a protective layer having an initial damage resistance, and a reactive layer. When the cable is subjected to a localized damaging force, the reactive layer responds by creating a corresponding localized self-healed region. The self-healed region provides the cable with enhanced damage resistance as compared to the cable's initial damage resistance. Embodiments of the invention utilize conventional epoxies or foaming materials in the reactive layer that are released to form the self-healed region when the damaging force reaches the reactive layer.

Abstract: A system (100, 200, 300) for damping vibrations of a vibratory structure (104, 308). The damping system includes an active damper (112, 124, 128, 216), a vibration sensor (116, 208, 208A?-C?), and a controller (120, 212) for controlling the active damper in a manner that damps vibration of the vibratory structure. In some embodiments, the active damper comprises an active mass (132, 220, 220A?-C?, 220A?-C?) and an actuator (136) for controlling the movement of the active mass. In other embodiments, the active damper comprises a flexural damper (128).

Abstract: Self-healing cable apparatus and methods disclosed. The cable has a central core surrounded by an adaptive cover that can extend over the entire length of the cable or just one or more portions of the cable. The adaptive cover includes a protective layer having an initial damage resistance, and a reactive layer. When the cable is subjected to a localized damaging force, the reactive layer responds by creating a corresponding localized self-healed region. The self-healed region provides the cable with enhanced damage resistance as compared to the cable's initial damage resistance. Embodiments of the invention utilize conventional epoxies or foaming materials in the reactive layer that are released to form the self-healed region when the damaging force reaches the reactive layer.

Abstract: A magnetic on-off robotic attachment device (MOORAD) (100, 300, 400, 624, 624?, 660, 676, 804) is used to make a number of systems, such as a mobile apparatus (608, 644, 668, 700, 700?), a belt mechanism (800) and a sensor device (504, 508, 656). The MOORAD allows the respective system to be removably magnetically attached to a ferromagnetic structure/object (228, 420, 604, 604?, 720A-B, 720A?-B?, 848). Each MOORAD generally includes a dipole magnet (104, 304A-B, 404) movable relative to first and second ferromagnetic portions (112, 116, 316A-D, 408, 412) that are separated by corresponding magnetically insulating portions (120, 320A-C, 416) so as to change that MOORAD between off and on states.

Abstract: A thermoelectric device (100, 342) that includes at least one thermoelectric couple (118, 304) that contains a thermoelectric junction (156) between two dissimilar materials (P, N) that allow exploitation of either the Seebeck effect or Peltier effect of the junction. The thermoelectric couple includes two thermoelements (120, 124, 324, 326) that extend between the hot side (104) and cold side (108) of the device. Each thermoelement has a thermally insulating region (128, 132) that insulates the hot side from the cold side and an electrical energy storage device (136, 138, 308, 310) that stores electrical energy. When operating in a Seebeck mode, each storage device may be periodically discharged by harvesting circuitry (200, 300) so as to harvest the energy stored therein. When operating in a Peltier mode, each storage device may be periodically charged by charging circuitry (900, 1000) so as to induce a temperature change at the thermoelectric junction.

Abstract: A method of curing a photosensitive material (10) having a critical electrical field amplitude at which photoinitiation occurs. The method includes contacting the photosensitive material, e.g., a photoinitiator/monomer resin system, with a substrate (18), such as an optical element, so as to form an interface (20) between the photosensitive material and the substrate. A light beam (12) is directed into the substrate such that the light beam is totally internally reflected from the interface within the substrate so that an evanescent wave is created in the photosensitive material. In order for curing to occur, the electric field amplitude of the evanescent wave at the interface must be at least equal to the critical electric field amplitude of the photosensitive material.