Chromatography devices contain chromatography media and methods of making and methods of using chromatography devices. Chromatography devices enable a more efficient, productive and/or environmentally friendly chromatographic operation due to one or more of the following advantages over conventional chromatographic operations: elimination of a device packing step by the user; elimination of clean-in-place (CIP) steps; elimination of clean-in-place (CIP) steps utilizing sodium hydroxide solution; elimination of any validation steps by the user; and use of a chromatography device comprising biodegradable material. The chromatography media includes porous inorganic particles having a functionalized surface and having a median pore size of at least about 300 Angstroms (A), or at least about 300 A up to about 3000 A. The inorganic particles may have a BET surface area of at least about 20 m2/g, or at least about 25 m2/g, or about 30 m2/g, up to about 2000 m2/g.

A vehicular exterior rearview mirror assembly includes a mirror reflective element and an illumination module that includes an illumination source and a freeformed lens optic. When the illumination source is operated to emit light, emitted light passes through the freeformed lens optic. The freeformed lens optic is configured such that, with the vehicular exterior rearview mirror assembly mounted at a side of a vehicle, light emitted by the illumination source that passes through the freeformed lens optic provides ground lighting that illuminates a ground region located at the side of the equipped vehicle. The ground lighting includes (a) ground illumination of the illuminated ground region and (b) within the ground illumination of the illuminated ground region, a logo formed by the freeformed lens optic. The logo formed by the freeformed lens optic has a light intensity greater than any light intensity of the ground illumination of the illuminated ground region.

A method of processing ultra high hardness steel is provided to increase its usefulness in armor applications. The method involves slowly cooling the ultra high hardness steel to a cryogenic temperature, slowly returning the steel to an ambient temperature, slowly heating the steel, and again slowly returning it to an ambient temperature.

A deployment instrument for deploying a closure device for sealing a percutaneous puncture in a wall of a body passageway, the deployment instrument including a carrier assembly, wherein the carrier assembly is configured to hold the closure device in a pre-deployment state, and a tensioner assembly, wherein the filament is fixedly attached to the tensioner assembly, wherein the deployment instrument is configured to increase the tension in the filament upon linear movement of the deployment instrument away from the wall of the body passageway when the closure device is anchored to the wall via the anchor such that the tension is gradually increased as the deployment instrument is moved between a first linear distance and a second linear distance greater than the first linear distance from the wall of the body passageway.

Systems, methods apparatuses, and computer-readable media for analyzing vehicle accident claim information from a vehicle that is deemed a total loss, as well as historical data, to determine whether one or more parts from the vehicle are available for reuse is presented. In some examples, aspects may also relate to determining whether the parts available for reuse should be stored by the entity using the system (e.g., the insurance company) for future use in the repair of other vehicles, such as other vehicles insured by the insurance company, or should be sold. The determination to store or sell the part may be based, at least in part, on historical data of the entity.

A novel latch seat for a switching rocker arm assembly used in variable valve actuation (VVA) systems for internal combustion engines. The seat is formed interactively in the assembled switching rocker arm using a novel fixture and press. The press interactively creates a curved dimple of the correct curvature, position and depth while measuring several lash dimensions. Since the latch seat is formed on the assembled rocker arm assembly, the latch seat depth is designed to account for the inaccuracies in the rocker arm assembly parts which create lash. Therefore all of the parts may be made with less precision since the latch seat is sized to compensate for the inaccuracies of all of the parts. The rocker arm assembly parts now may be manufactured to less stringent standards, but result in a rocker arm assembly with same accuracy of rocker arm assemblies manufactured to previous standards.

A vibration isolation apparatus includes a support unit that elastically supports an object to a mounting surface, a measurement sensor that measures a displacement of the object relative to the mounting surface, a drive unit that drives the object, and a storage unit. The storage unit stores data indicating a relationship between the displacement of the object and information that indicates a non-linear force produced by an elastic element including a support unit and that corresponds to the displacement. The drive unit drives the object in accordance with the displacement of the object and the data.

A suspension coil spring, when assembled to a suspension device, in which a spring reaction axis (AR) is positioned coincident with or sufficiently close to a load input axis (AA), and the design and manufacture of coil springs are facilitated. Namely, a suspension coil spring (10) in a free state is formed so that a coil axis (AC) is bent in V-shape at bend point (PB) and the distance from the end turn center (CU) of the upper seating surface (38) to an imaginary coil axis (AI) is an upper inclination amount (V.sub.U), and the distance from the end turn center (CL) to the imaginary coil axis (AI) is a lower inclination amount (V.sub.L). When the suspension coil spring (10) is interposed between spring seats (22, 24) in the suspension device and compressed along a strut axis, the spring reaction AR axis of the suspension coil spring (10) is inclined and offset with respect to the imaginary coil axis (AL) according to the inclination amounts (V.sub.U, V.sub.L).

A travel system (20) for a canister storage, transfer, or transport system generally includes a support structure (22), at least one traveling device (24) for preparing, inspecting, and/or repairing the canister, and a base ring (26) for supporting the traveling device and providing for rotational movement of the traveling device relative to the support structure.

An illumination module configured for mounting at a vehicle includes at least one illumination source and an optic. The optic is a three dimensional single formed optic that is formed such that, when the illumination source is operated and when the illumination module is disposed at a side of a vehicle, the optic provides projection of an icon, a logo and/or indicia at a ground region at or near the side of the vehicle. The optic includes one of (a) a lens optic configured such that light emitted by the illumination source, when activated, passes through the lens optic to provide projection of the icon, the logo and/or indicia, and (b) a reflector optic configured such that light emitted by the illumination source, when activated, reflects off the reflector optic to provide the selected projection of the icon, the logo and/or indicia.