Abstract: A test rack for a storage device testing system includes a plurality of test slot carriers. Each of the test slot carriers includes a plurality of test slot assemblies. The test slot assemblies are configured to received and support storage devices for testing. The test rack also includes a chassis. The chassis includes a plurality of carrier receptacles for releasable receiving and supporting the test slot carriers. The test slot carriers are interchangeable with each other among the various carrier receptacles.

Abstract: A sensor module includes a housing having a top and a bottom. A mounting surface is positioned proximate to the bottom of the housing. A sensor is positioned within the housing. A fixed component extends from the top of the housing. A moveable component is provided having a mounting surface. The moveable component is selectively coupled to the fixed component to variably position the mounting surface of the moveable component relative to the mounting surface of the housing.

Abstract: Systems, methods and apparatus are provided through which in some implementations a retractable environmental detector system includes two portions, a base or retractor unit that can be attached to a ceiling and a retractable environmental detector operably coupled to the base or retractor through a flexible retractable connector that retracts and extends the retractable environmental detector from and to the base or retractor.

Abstract: A sensor device has a structural element, a carrier element and a housing, the structural element being situated on the carrier element, and the structural element and the carrier element being situated at least partially within the housing. The sensor device also has an intermediate housing, which is situated essentially between the housing and the structural element, the intermediate housing including a premold housing.

Abstract: A physical quantity sensor includes a sensor portion, a casing, and a vibration isolator. The casing includes a supporting portion with a supporting surface that is located to face an end surface of the sensor portion. The vibration isolator is located between the end surface of the sensor portion and the supporting surface of the casing to join the sensor portion to the casing. The vibration isolator reduces a relative vibration between the sensor portion and the casing.

Abstract: A gas monitoring apparatus and system that provides for reliable and accurate monitoring of gaseous hydrogen and other compounds in dielectric oil. The apparatus provides an environment for and is used in conjunction with metal oxide semiconductor sensors. Apparatus for creating a fluid-tight environment for the metal oxide semiconductor and a heating manifold are detailed.

Abstract: A liquid natural gas sample conditioning cabinet structure with a covered vent disposed proximate to the cabinet floor for preventing pooling of and venting heavier-than-air hydrocarbon gases.

Abstract: A sensor assembly includes a metal carrier plate (2) and a sensor housing (3) made of plastic that contains at least one sensor element. The sensor housing (3) is connected to the carrier plate (2) by means of at least one screw (5) that is passed through a through hole (6) of the carrier plate (2). A screwing channel (7) in the sensor housing (3) is defined by the housing material. As a result, a sensor assembly is obtained where the screwed connection is secure.

Abstract: The present sensing device comprises a sensor (1) for providing sensor data representative of a quantity to be measured. Together with the sensor (1) a radio frequency interface (2) for transmitting the sensor data is arranged in a casing (3). The casing (3) comprises an opening (33) for exposing a sensitive element (11) of the sensor (1) to an environment of the casing (3). A seal (4) is provided for sealing the opening (33) against an interior (3) of the casing (3). The sensing device can be used as autonomous humidity detector for detecting humidity e.g. in cars under test.

Abstract: The invention relates to a metallic sensor housing for an optoelectronic sensor which is composed of a plurality of parts. Provision is made in accordance with the invention that two or more metallic parts of the housing are connected to one another with material continuity. The invention additionally relates to an optoelectronic sensor having a metallic sensor housing in accordance with the invention and to a method of manufacturing a metallic sensor housing in accordance with the invention.

Abstract: An apparatus for pedalling measurement is presented. The apparatus comprises a casing arranged to be attached to a crank of a cycle. The casing comprises a signal processing circuitry configured to process a measurement signal related to pedaling. The casing further comprises a protrusion arranged to be disposed at least partially into a hole of a spindle of a pedal, wherein the protrusion provides the apparatus with a mechanic support with respect to the spindle and an electric connection between the signal processing circuitry and a measurement circuitry comprised in the spindle. Furthermore, there is provided a cycling apparatus comprising the above-mentioned apparatus.

Abstract: An environmental testing device includes a humidity control module, a temperature control module; and an air circulation module. The air circulation module includes an enclosure and a fan received in the enclosure. Two pairs of airflow openings are defined in the enclosure and form different airflow passages that allow air to flow along different directions in the environmental testing device.

Abstract: A disk drive transporter, for transporting a disk drive and for mounting a disk drive within a test slot, includes a frame configured to receive and support a disk drive. The frame includes sidewalls configured to receive a disk drive therebetween and sized to be inserted into a test slot along with a disk drive. The frame also includes a clamping mechanism operatively associated with at least one of the sidewalls. The clamping mechanism includes a first engagement element and a first actuator operable to initiate movements of the first engagement element. The first actuator is operable to move the first engagement element into engagement with a test slot after a disk drive being supported by the frame is arranged in a test position in a test slot.

Abstract: A method for fixing a functional component (2) in a housing (4). During a first step, a first housing portion (1) is prepared in which a functional component (2), to be fixed, is arranged in a provisional fixing position. During a second step, a second housing portion (3) is arranged in contact with the first housing portion (1) so that the functional component (2) is arranged in a joining direction (X) between the housing portions (1, 3). During a third step, material from at least one of the housing portions (1, 3) is melted in such manner that the functional component (2) between the housing portions (1, 3) is gripped in position by them when a material-integral bond is formed between the housing portions (1, 3). Also, an arrangement which can be produced by the method.

Abstract: Provided is a sensor structure capable of improving the reliability of connecting parts of electronic components and achieving excellent productivity and reduction in size and weight, for example, when electronic components are externally mounted on input/output terminals of a sensor. A relationship between a linear expansion coefficient for a housing serving as a base of a structure and a linear expansion coefficient of a resin material for a sensor casing of a sensor to be mounted is set to satisfy “sensor casing<linear expansion coefficient ?<housing”. When electronic components are externally mounted, the electric components are mounted on input/output terminals which are integrally formed on the side of a component having a small linear expansion coefficient, i.e., on the side of the sensor casing.

Abstract: An intrinsically safe housing for a measuring instrument, having a viewing window for the display panel of a measuring instrument, an instrument display panel holding fixture for receiving an instrument display panel provided around the viewing window, said holding fixture having an inner void having a volume greater than a volume of the instrument display panel, a difference between said volumes forming a resin slot surrounding the instrument display panel upon its insertion, and a seal holding fixture provided around the viewing window containing a seal for sealing a front surface of said display panel, wherein the seal and the display panel holding fixture form a resin receptacle for a flowable resin, and the resin slot receives an overflow of said resin upon insertion of said instrument display panel.

Abstract: A measuring device with at least one housing and at least one electronic unit, wherein the housing has at least one electronic access opening for the electronic unit, wherein a first longitudinal axis extends through the electronic access opening, wherein the housing has a sensor access opening for connecting to a sensor unit, wherein a second longitudinal axis extends through the sensor access, wherein the first longitudinal axis and the second longitudinal axis span an orientation plane, wherein the electronic unit has at least one printed circuit board which lies essentially in a printed circuit board plane that, to provide a measuring device, in which the effect of external mechanical stresses on electronic components can be reduced, is arranged in the housing such that the printed circuit board plane is at an angle relative to the orientation plane which differs from an integral multiple of 90°.

Abstract: A measuring sensor includes an elongated shell part, manufactured from a synthetic gemstone material or ceramic material, is provided with a first end and a second end, the first end being arranged in a process medium to be measured. A housing structure is manufactured from a material softer than the synthetic gemstone material or the ceramic material and arranged to surround the measuring electronics. The second end of the elongated shell part is arranged to be supported against the housing structure. The elongated shell part is fastened to the housing structure by a connecting piece manufactured from a material having a hardness property between hardness properties of the material of manufacture of the elongated shell part and the material of manufacture of the housing structure.

Abstract: A sensor apparatus includes a first elongated housing to at least partially enclose a sensor device and a second elongated housing coupled longitudinally to the first elongated housing. The second elongated housing includes at least one radial port extending from an inner surface to an outer surface of the second elongated housing to allow a first material received through an opening of the second elongated housing to flow through the second elongated housing and out the radial port in the vicinity of the sensor apparatus.

Abstract: A sensor mounting cover is for a rolling-contact bearing and includes a transverse wall and an axial projection joined to the transverse wall and provided with a through-seat for housing a sensor. The sensor faces the bearing from a window defined by an inner edge of the seat and a closure element is associated with the axial projection and is arranged at least around the inner edge so as to close the window.

Abstract: An explosion-proof device with a pressure-proof capsule (2), an electronic mechanism (3) and a signal receiver (4), wherein the electronic mechanism (3) is designed intrinsically safe, the pressure-proof capsule (2) has a radiolucent process window (5) and the signal receiver (4) is arranged inside of the pressure-proof capsule (2). An explosion-proof device that can be flexibly used and is economical is implemented in that the electronic device (3) is arranged within the pressure-proof capsule (2) and the signal receiver (4) is designed to be intrinsically safe.

Abstract: A spectroscopic instrument comprising a compartment (2) for housing instrument components (3) and desiccant (4) to protect the instrument components, and a deformable container (5) having at least one wall portion which is movable within the compartment (2) so as to vary the volume of the compartment (2) that is occupied by the deformable container as the container is deformed. The interior of the deformable container (5) is in fluid communication with the surroundings of the instrument, such that a difference in pressure between the compartment and the surroundings tends to cause the deformable container to deform, moving the wall portion.

Abstract: A gas sensor comprises a gas sensing element, a storage medium to store individual information prepared individually for the sensing element for use in control of the sensing element, and a circuit board supporting the storage medium mounted on the circuit board. A seal portion of a resin covers the circuit board liquid-tightly. An output base includes a mount surface facing to the circuit board. A terminal portion extending through the mount surface is connected with the circuit board and arranged to deliver the individual information through the circuit board. The output base further includes a support projection projecting from the mount surface and including a support surface supporting the circuit board.

Abstract: The invention provides a housing for a sensor having a semiconductor element for measuring hydrogen concentration in an insulating fluid in electric power generation, transmission, and distribution equipment having a mounting flange on the equipment providing access to the interior of the equipment and provided with a plurality of bolt receiving openings arranged on the mounting flange in a first pattern, which includes a first flange having at least one or more openings for receiving one or more semiconductor hydrogen sensors and an outer periphery, a plurality of bolt receiving apertures arranged in a pattern corresponding to the first pattern within the outer periphery of the first flange, a second flange having a second plurality of bolt receiving apertures arranged in a pattern corresponding to the first pattern within the periphery of the second flange.

Abstract: Valve comprising a shutter (2) rotating as one (A) with a shaft (3) and a sensor sensing the rotational position of the shaft (3), which comprises a target holder (4a) push-fitted onto the shaft (3), a plate (6) slipped onto the shaft (3), the target holder (4a) and the annular part (6a) being in one and the same plane.

Abstract: A system includes a structure and a component. The component including an energy providing device and a protective cover. The structure has a structure surface. The protective cover has a protective cover attachment surface mounted on the structure surface. The energy providing device is located within the protective cover. The protective cover has a protective cover outer surface. The protective cover outer surface is oriented to face a first direction from which an impact load may strike the protective cover outer surface and shear the protective cover from the structure surface. The protective cover outer surface has an outer surface shape facing the first direction. At least a portion of an impact load striking any region of the protective cover outer surface facing the first direction is transferred by the outer surface shape into a compression load.

Abstract: A sensor system having a sensor element, a housing in which sensor element is situated and which seals the sensor element from the outside world, at least one first electrical contact element which is electrically coupled with the sensor element; a plug connector, which has at least one second electrical contact element, and at least one spring element which is coupled between the at least one second electrical contact element and the at least one first electrical contact element for electrical contacting, so that the sensor element is electrically connected to the second electrical contact element of the plug connector.

Abstract: Embodiments of the present invention provide improved systems and methods for external frit mounted components on a sensor device. In one embodiment, a method for fabricating a sensor device comprises securing at least one component stack on a sensor body over at least one opening in the sensor body, wherein the at least one component stack comprises a plurality of components and applying a frit to the plurality of components in the at least one component stack and the sensor body. The method further comprises heating the frit, the at least one component stack, and the sensor body such that the frit melts and cooling the frit, the at least one component stack, and the sensor body such that the at least one component stack is secured to the sensor body.

Abstract: A device for mounting on a structure surface includes a component, a circuit, a moisture barrier, and a protective cover. The moisture barrier is within the protective cover. The component and the circuit are within the moisture barrier. The component is for bonding to the structure surface with a bond susceptible to damage from moisture. The circuit includes a radio frequency transmitter. The circuit is for providing data derived from the component to the radio frequency transmitter for external transmission.

Abstract: A device for mounting on a structure surface includes a component, a circuit, a moisture barrier, and a protective cover. The moisture barrier is within the protective cover. The component and the circuit are within the moisture barrier. The component is for bonding to the structure surface with a bond susceptible to damage from moisture. The circuit includes a radio frequency transmitter. The circuit is for providing data derived from the component to the radio frequency transmitter for external transmission.

Abstract: A junction box for a probe is disclosed for connecting to a sensor assembly of the probe, wherein the sensor assembly has a housing and a plate. The junction box comprises stopper walls, retaining flanges, and a retainer spring to secure the plate junction box. The probe can be assembled by inserting the sensor assembly through the opening, pressing the plate onto the at least one retainer spring and elastically deforming the at least one retainer spring, and rotating the sensor assembly into an assembled position.

Abstract: The invention relates to A sensor end module, comprising: a sensor cap having a first connecting element and a sensorially active element for contact with a medium; and a memory module, comprising: a housing having a second connecting element, wherein the second connecting element enters into a shape- and/or force interlocking connection with the first connecting element; a memory element, wherein the memory element contains information concerning the sensorially active element the memory element is arranged in or on the housing; a first communication interface for sending and/or receiving information and/or data, and wherein the first communication interface is in electrical contact with the memory element. Furthermore, the invention relates to a sensor and a measuring system.

Abstract: There is provided a sensor module that is readily attachable to and detachable from a mobile terminal, can incorporate a sensor function at low development cost and is capable of maintaining the waterproofness of a mobile phone. The sensor module of the present invention comprises a housing, a sensor element, a sensor data processing part, a sensor data recording part, contactless communication means, a module communication part and a module control part. The housing has attaching means for attaching and detaching the sensor module to and from a mobile terminal. The sensor data processing part acquires data from the sensor element and performs predetermined processing on the acquired data.

Abstract: A sensor module and method for producing the sensor module including a chip carrier and a sensor chip disposed thereon. The sensor module includes at least one partial cover having a recess on a second face of the chip carrier, such that heat from the chip carrier and/or the sensor chip can be dissipated to the recess.

Abstract: The present invention relates to gas sensor housing (1), comprising: a gas sensor (3) held by a housing body (11) below a primary gas permeable membrane (2); at least one connector element (10) moulded into the housing body (11) such that the respective ends thereof enable connectivity to the gas sensor (3) such that signals may be carried from the gas sensor (3) to the connector element (10); a sensor envelope (9) providing an enclosure for the housing body (11); means for retaining the primary gas permeable membrane (2) in place above the gas sensor (3); a spacer section (7) providing a separation distance (X) between the gas sensor (3) and the primary gas permeable membrane (2).

Abstract: A sensor unit for attachment to a container such as a bag or other vessel used to retain material includes a clamping mechanism for attaching the sensor unit to the container. The clamping mechanism may be configured to break or provide an indication that the connection between the sensor and container has broken that is visually detectable before a leak of material occurs or is detectable by a person visually monitoring the container or sensor. Such an indication can also indicate that the sensor was previously used and should not be used again for single use applications. Such a visual indicator is separate and different from seeing an actual leak and permits an event that may desterilize material within the container or lead to other problems to be corrected prior to use of a single use reaction system.

Abstract: A manifold gauge cover featuring a first half shell and a second half shell connected via a hinge. The inner surfaces of the shells are lined with foam. The shells can move between an open position and a closed position respectively allowing and preventing access to the inner cavities of the shells. A locking mechanism secures the shells in the closed position. A gauge aperture is disposed in the back surfaces of the shells to allows passage of the hook of a manifold gauge set. A magnet is disposed on the bottom surface of a shell. A chart holder is disposed on the top surface of a shell adapted to hold a pressure temperature chart. When the half shells are in the closed position, the half shells cover a portion of a manifold gauge set.

Abstract: The invention relates to a sensor, comprising a sensor element (1) that operates without contact, an electronic component (5), and a housing (2) having an electrical/electronic connection. The sensor element (1) is part of the housing (2) and is used to close and seal the housing (2) with respect to the measurement side (3).

Abstract: A stabilized field sensor apparatus collects field data, in particular magnetic field data, with reduced motion noise. The apparatus includes a tear drop shaped housing, a tow frame in the housing, a plurality of vibration isolating dampers spaced around the frame, a base assembly mounted to the dampers, a support pedestal having a bottom end fixed to the base assembly and an upper free end, a single spherical air bearing connected to the upper free end of the pedestal, an instrument platform with a lower hollow funnel having an upper inside apex supported on the air bearing for a one point support, principal and secondary gyro stabilizers for maintaining pivotal and rotational stability, and at least one field sensor mounted to the instrument platform for collecting the field data while being stabilized against motion noise including vibration, pivoting and rotation from the base assembly, from the tow frame and from the housing.

Abstract: A composite material comprises a polymer matrix; and zeolite, which is bonded in the polymer matrix; wherein the percent of volume of the zeolite in the volume of the composite material amounts to at least 50%, in particular at least 65%. The polymer matrix can in particular comprise a polymer, which is selected from a group of polymers that consist of fluoroplastics, polyaryletherketones, sulphur-containing polymers and high heat resistant polymers. The zeolite comprises in particular a zeolite of type A, in particular a zeolite 4A or 3A.

Abstract: A leadthrough with a sensor section comprising a component section or tube section with a component wall thickness or tube wall thickness and least one sensor section for accommodating a sensor with a sensor wall thickness. The leadthrough with a sensor section is characterized in that the sensor wall thickness is smaller than half the component wall thickness or the tube wall thickness.

Abstract: A tight package sensor seal includes a first seal portion engaging an outer surface of a sensor body and including a stop surface floatingly engaging a peripheral face surrounding a bore in a cover member. The first seal portion includes a reinforcing insert disposed therein. A second seal portion is axially spaced from the first seal portion and a flexible membrane extends axially between the first and second seal portions. The second seal portion engages an inner diameter of a bore in a cover member and includes a reinforcing insert therein. The sensor seal takes up a small radial space yet allows for radial offset of the sensor body relative to the bore of the cover member.

Abstract: A retractable assembly for a sensor, which determines a physical and/or chemical, process variable in a process medium. The retractable assembly has a housing, in which a tubular holder for accommodating the sensor is arranged such that it can be moved linearly by a drive unit. At least one cascaded cylinder is provided for the linear shifting of the tubular holder, wherein the cascaded cylinder comprises at least two cylinders arranged one after the other in the direction of the stroke movement. Furthermore, the cascaded cylinder is, or the cascaded cylinders are, embodied and/or operable in such a manner that the sensor is movable into at least two different positions.

Abstract: A sensor assembly for use in a vehicle. The sensor assembly has a housing for receiving a substrate. Terminals with substrate mating portions are provided in the housing. The substrate has components mounted thereon and plated openings which extend therethrough. The plated openings are provided in electrical engagement with the terminals. The openings are provided to mechanically and electrically engage the resilient contact portions of the terminals. The substrate mating portions are releasably pressure fit within the plated openings to allow the substrate to be removed and replaced as needed. The substrate mating portions maintain the electrical and mechanical connection between the substrate mating portions and the plated openings when the sensor assembly is exposed to vibration.

Abstract: A controller for a motor vehicle with a carrier plate for receiving a component carrier with a component carrier foot. The carrier plate has a recess through which the component carrier can be passed and which is suitable for receiving the foot, wherein the dimensions of the recess in the region of the component carrier and in the region of the foot in the X/Y-direction correspond to maximum admissible dimensions of the component carrier and of the foot (5) in the X/Y-direction. In the Z-direction, a pressing geometry is arranged on the recess or on the foot such that after establishing a positive-fit or non-positive connection between the carrier plate and a system interface, the pressing geometry or a part that is arranged opposite the pressing geometry is in such a deformed state that the foot is in the recess in a fixed state and without play.

Abstract: A vehicular ultrasonic sensor apparatus serving as a distance sensor apparatus is equipped with a sensor unit, a case body, a bezel, and a retainer. The retainer includes a pair of pawl members. The pair of pawl members is equipped with a stopper portion. The ultrasonic sensor apparatus is inserted into an attachment hole of the bumper such that a connector portion of the case body is first inserted. When the retainer passes through the attachment hole, the pair of pawl members are elastically deformed. After passing through the attachment hole, the pair of pawl members are elastically restored, and the stopper portion is caught at an inner circumference edge of an exit side of the attachment hole.

Abstract: A collision sensor module configured to be attached to a surface of a vehicle. The module includes a collision sensor circuit board configured to detect acceleration indicative of a vehicle collision event. The exterior of the module is defined by a housing that includes a rigid part and a flexible part. The rigid part is configured to define a wing portion for attaching the rigid part to the surface, provide an underside surface of the rigid part to couple the collision sensor circuit board to the surface in a manner effective for the circuit board to detect when the vehicle is involved in a collision event. The flexible part is configured to sealingly contact the rigid part and the collision sensor circuit board in a manner effective to seal the protective cavity when the rigid part is attached to the surface and thereby protect the collision sensor circuit board.

Abstract: The present disclosure provides for systems and methods for fabricating measuring devices, e.g., a pressure gauge, thermometer or the like. More particularly, the present disclosure provides for systems and methods for fabricating measuring device assemblies having zero/span adjustable linkage movements (e.g., zero/span adjustable four-bar linkage movements). In general, the present disclosure provides for measuring device assemblies having zero/span adjustable linkage movements, wherein the zero/span adjustable linkage movements do not adversely affect linearity of the measuring device assemblies, and wherein the measuring device assemblies are rugged and able to withstand certain extreme shock and/or vibration conditions.

Abstract: The disclosure relates to a storage apparatus for a measurement probe for use with a coordinate positioning machine. The storage apparatus has at least one receptacle for a measurement probe. At least one receptacle connector is provided for electrical connection with at least one probe connector on a measurement probe located in the receptacle. The one receptacle connector is configured such that it can be displaced so as to disconnect it from the probe connector of a measurement probe located in the receptacle.

Abstract: The gauge lens with anti-fog film includes a substantially planar transparent lens substrate having an outer surface and an inner surface and a thin film possessing anti-fog properties adjacent and substantially covering the inner surface of the lens substrate to provide a low angle of contact for water and moisture. The anti-fog film is bonded to the lens substrate during the molding process that produces the lens substrate shape. The anti-fog film comprises a hydrophilic material or is coated with a hydrophilic coating. In addition to the anti-fog film, in another embodiment, the outer surface of the lens substrate has a hard coat film adjacent and substantially covering the outer surface of said lens. The materials for the lens substrate, anti-fog film, and hard coat film are selected based on the application, performance, and stability of the gauge lens in the environment that it is operated.