71results about How to "Sufficiently robust" patented technology

A compliant interface (14,16) for vehicular seat weight sensors minimizes parasitic stresses affecting sensor output. In one embodiment, an integral compliant interface (14) has an annular flange (14a) attached to a post extending from the sensor body with a first compliant member (14r) disposed between the annular flange and an upper elongated flange (14h) of a mounting bracket (14l) and a second compliant member (14s) disposed between the annular plate and a lower elongated flange (14k) to allow pivotal movement of the sensor limited by a motion stop member (14f) of annular flange (14b) engaging the lower flange. An overload cage (14u) may be placed over the sensor and attached to an additional flange (14l) to contain the sensor in the event of a failure of the mount in a catastrophic high speed crash. According to another preferred embodiment, an interface having upper and lower body members are formed with a sensor post receiving bore (16c) for attachment to the post. The body members are formed with spaced apart, radially extending face surfaces, each formed with an annular recess aligned with each other and with a compliant member received therein and fixed to the respective body members and extending beyond the face surfaces. The interface is received through a bore of a support plate to which the sensor is mounted with the compliant members engaging opposite face surfaces of the support plate allowing limited pivotal motion and with a compliant member limiting lateral movement of the interface relative to the support plate.

A light emitting diode includes a first doped semiconductor layer, an active region and a second doped semiconductor layer. The first reflective electrode of the light emitting diode is connected to the edge surfaces of the first doped semiconductor layer. The second reflective electrode includes an optically transparent layer and is connected to the second doped semiconductor layer. The second reflective electrode may include a plurality of electrically conductive contacts extending from a reflective conductive metallic layer through a transparent layer. A method is described for fabricating the light emitting diode.

The present invention involves porous polymer membranes, suitable for use in medical implants, having controlled pore sizes, pore densities and mechanical properties. Methods of manufacturing such porous membranes are described in which a continuous fiber of polymer is extruded through a reciprocating extrusion head and deposited onto a substrate in a predetermined pattern. When cured, the polymeric material forms a stable, porous membrane suitable for a variety of applications, including reducing emboli release during and after stent delivery, and providing a source for release of bioactive substances to a vessel or organ and surrounding tissue.

A lock mechanism operated by inner and outer lever handles provides a security classroom function and includes inner and outer lock mechanisms that are independently switchable between locked and unlocked states by inner and outer lock cylinders and keys. The inner handle always operates the lock mechanism to retract a latch bolt. The outer handle can only retract the latch bolt when both the inner and outer lock mechanisms are in the unlocked state. The outer key can retract the latch bolt when the inner lock mechanism is in the locked state, but cannot change the inner lock mechanism to the unlocked state or enable the outer handle, thereby ensuring positive control over the locked state of the outer handle from the inner side.

A compliant interface (14,16) for vehicular seat weight sensors minimizes parasitic stresses affecting sensor output. In one embodiment, an integral compliant interface (14) has an annular flange (14a) attached to a post extending from the sensor body with a first compliant member (14r) disposed between the annular flange and an upper elongated flange (14h) of a mounting bracket (14l) and a second compliant member (14s) disposed between the annular plate and a lower elongated flange (14k) to allow pivotal movement of the sensor limited by a motion stop member (14f) of annular flange (14b) engaging the lower flange. An overload cage (14u) may be placed over the sensor and attached to an additional flange (14l) to contain the sensor in the event of a failure of the mount in a catastrophic high speed crash. According to another preferred embodiment, an interface having upper and lower body members are formed with a sensor post receiving bore (16c) for attachment to the post. The body members are formed with spaced apart, radially extending face surfaces, each formed with an annular recess aligned with each other and with a compliant member received therein and fixed to the respective body members and extending beyond the face surfaces. The interface is received through a bore of a support plate to which the sensor is mounted with the compliant members engaging opposite face surfaces of the support plate allowing limited pivotal motion and with a compliant member limiting lateral movement of the interface relative to the support plate.

A high-sensitivity pressure conduction sensor is presented. The present invention includes a pair of locally resilient conductive layers and a locally resilient pressure conduction composite disposed between and contacting both conductive layers. Alternate embodiments include at least three locally resilient conductive layers and at least two locally resilient pressure conduction composites, each having a critical percolation threshold. Each composite is disposed between and contacting two conductive layers in a multi-layer fashion. Other embodiments include a locally resilient pressure conduction composite, a flexible substrate completely surrounding the composite so as to seal it therein, and a pair of electrical leads contacting the composite and terminating outside of the flexible substrate. Pressure conduction composites are composed of a plurality of conductive particles electrically isolated within a non-conductive matrix. Conductive particles are loaded so as to have a volume fraction approaching the critical percolation threshold of the material system and exhibit a conductance that greatly increases with pressure. Sensors may be arranged to form one or more arrays including planar and conformal configurations. The present invention has immediate application in keyboards, intrusion systems, control systems, submarines, ships, sonobuoys, doors, and switches.

A motorized antenna positioning mechanism in a portable microwave communication unit for use as a ground station in a satellite communication system. The antenna positioner has compact and low profile azimuth wire drive mechanics, azimuth and polarization angle sensors that are not affected by slippage and backlash, and an elevation drive mechanism which neutralizes the pressure on the motor axis due to the weight of the parabolic antenna.

Systems, methods and kits relating to in-situ forming polymer foams for the treatment of aneurysms or fluid filled spaces are disclosed. The systems include an insertable medical device and an in-situ forming foam of lava like materials with a fast forming outer skin and a slower hardening interior that is formed from a one-, two- or multi-part formulation. When used to treat an aneurysm, the foam is placed into contact with at least a portion of an exterior surface of the medical device and / or the tissue surface of the aneurysm.

A method of producing a CMC article having a net shape, and by which the article can be formed to have an exterior surface with desirable characteristics, such as being free of an imprint pattern of a fiber reinforcement material within the article. The method entails providing a body comprising the fiber reinforcement material, and depositing a coating on a surface of the body. The coating contains a carbonaceous binder and a slurry containing a ceramic particulate material. Following its deposition, the carbonaceous binder within the coating is cured to render the coating machinable, and the coating is then machined to approximately produce the net shape of the article.

A humane animal trap includes an enclosure having an opening with a door disposed therein. The door is pivotable about an upper edge between open and closed positions, and is biased toward the closed position by a torsion spring. An electrical solenoid is disposed above the door and has a catch that is biased into engagement with a holding feature on the door when the door is in the open position, and is operable to disengage the catch from the holding feature in response to the receipt of an electrical trip signal. An electrical sensor disposed in the enclosure transmits a light beam between opposite sidewalls of the trap, and generates an electrical trip signal and transmits it to the solenoid when the light beam is interrupted by an animal entering the trap so as to close the door behind the animal and thereby capture it unharmed in the enclosure.

A method for fabricating an epitaxial substrate. The technique includes providing a crystalline or mono-crystalline base substrate, implanting atomic species into a front face of the base substrate to a controlled mean implantation depth to form a zone of weakness within the base substrate that defines a sub-layer, and growing a stiffening layer on a front face of the base substrate by using a thermal treatment in a first temperature range. The stiffening layer has a thickness sufficient to form an epitaxial substrate. In addition, the method includes detaching the stiffening layer and the sub-layer from the base substrate by using a thermal treatment in a second temperature range higher than the first temperature range. An epitaxial substrate and a remainder of the base substrate are obtained. The epitaxial substrate is suitable for use in growing high quality homoepitaxial or heteroepitaxial films thereon.

A method for fabricating an epitaxial substrate. The technique includes providing a crystalline or mono-crystalline base substrate, implanting atomic species into a front face of the base substrate to a controlled mean implantation depth to form a zone of weakness within the base substrate that defines a sub-layer, and growing a stiffening layer on a front face of the base substrate by using a thermal treatment in a first temperature range. The stiffening layer has a thickness sufficient to form an epitaxial substrate. In addition, the method includes detaching the stiffening layer and the sub-layer from the base substrate by using a thermal treatment in a second temperature range higher than the first temperature range. An epitaxial substrate and a remainder of the base substrate are obtained. The epitaxial substrate is suitable for use in growing high quality homoepitaxial or heteroepitaxial films thereon.

A humane animal trap includes an enclosure having an opening with a door disposed therein. The door is pivotable about an upper edge between open and closed positions, and is biased toward the closed position by a torsion spring. An electrical solenoid is disposed above the door and has a catch that is biased into engagement with a holding feature on the door when the door is in the open position, and is operable to disengage the catch from the holding feature in response to the receipt of an electrical trip signal. An electrical sensor disposed in the enclosure transmits a light beam between opposite sidewalls of the trap, and generates an electrical trip signal and transmits it to the solenoid when the light beam is interrupted by an animal entering the trap so as to close the door behind the animal and thereby capture it unharmed in the enclosure.

A cab suspension device for an agricultural tractor comprising a pair of concentrically aligned tubes co-axially arranged around a conventional cab suspension spring apparatus. One of the pair of tubes is connected to the tractor frame while the second is attached to the cab frame. The lengths of the tubes are shorter than the static length of the spring apparatus to allow limited telescoping movement of the tubes during dynamic compression of the spring apparatus without causing contact between the tube ends and the opposing tractor and cab frames. The dynamic extension during telescoping movement of the spring apparatus is controlled by a spring retainer. An annular space between the tubes allows for limited lateral displacement of the spring apparatus without causing contact between the tubes. The limits are configured to permit normal operational movement of the spring apparatus without contact of the tubes. During vehicle roll over events, the normal operational loads of the spring apparatus are exceeded and the tubes will come in contact with one another and / or the opposing frame. The tubes and the spring retainer provide a rigid load transfer path for ROPS loads from the cab to the vehicle frame.

Lysing may include agitating a specimen in a chamber along with a medium that includes a particulate lysing material that has an affinity for a biological material. Lysing material may include beads or other material which may be coated that facilitates binding. The medium may include a fluid with a high salt or low pH level. Binding of biological materials to solid surfaces may be induced by particular media. The biological material may be eluted by lowering a concentration of salt or increasing a pH level. Lysing materials with two or more different affinities may be employed. Lysing materials may include particles of different sizes. Heating may be used. Lysing may be performed in a flow through apparatus. Surfaces of solid materials may be modified to capture bacteria with high cell wall lipid content.