The disclosure relates to a system for measuring the position of an object in a measurement volume, including: an optical angular measurement device, disposed with static optics, configured for measurement of the an azimuth and elevation angle of the object in the measurement volume with respect to the optical angular measurement device, a range measurement device, disposed with static component, configured for measurement of the range of the object in the measurement volume. It further relates to a use of the system and a measurement method.

There is provided a profile measuring apparatus, including: an irradiation section configured to irradiate a measurement light to a measurement area of the object; an imaging section configured to obtain an image of the measurement area; a table configured to place the object thereon; a coordinate calculation section configured to calculate a position of the measurement area based on an image detected by a detection section; and a positioning mechanism configured to drive and control a relative position of the imaging section and the table. The positioning mechanism calculates a relative position of the imaging section to the table, based on an information with respect to an edge line direction of a convex portion or an extending direction of a concave portion in the measurement area of the object having a repetitive concave-convex shape, to move at least one of the table and the imaging section.

An automated grommet installer and methods of installing a grommet. The installer and methods are capable of seating a grommet in an aperture of a window and facilitating correct alignment of the grommet within the window. Grommets are used to support and seal around a window wiper attached to a window. Typically, grommets are asymmetrical to match the curvature of the window. Embodiments of the described installer maintain grommet orientation while inserting the grommet in the window, quickly and efficiently installing the grommet. In embodiments the installer includes a system for identifying an incorrectly loaded grommet prior to installation and alerting an operator. In other embodiments, the installer includes a positioner that positions the grommet proximate to the window for installation and a gripper having one or more fingers reach through the window aperture, engage the grommet, and draw it into position, seated in the window.

A method and a system are provided for predicting and creating a shim for use in a joint where two parts, such as a skin and a substructure, are assembled together. Digital models for the skin and the substructure may be used as nominal maps of the outlines and profiles of the parts. The skin may be inspected, e.g., by nondestructive means, such as ultrasound, to determine as-built thickness profile for comparison to the skin's digital model of the thickness profile. Mating areas of the skin and substructure may be determined from their digital models of their outlines. Deviations in the mating areas of the as-built thickness of the skin from the digital model of the skin may be used to generate a digital model of a shim. The shim may be constructed from its digital model by additive manufacturing techniques that may involving machining or 3D printing.

There is provided a profile measuring apparatus, including: an irradiation section configured to irradiate a measurement light to a measurement area of the object; an imaging section configured to obtain an image of the measurement area; a table configured to place the object thereon; a coordinate calculation section configured to calculate a position of the measurement area based on an image detected by a detection section; and a positioning mechanism configured to drive and control a relative position of the imaging section and the table. The positioning mechanism calculates a relative position of the imaging section to the table, based on an information with respect to an edge line direction of a convex portion or an extending direction of a concave portion in the measurement area of the object having a repetitive concave-convex shape, to move at least one of the table and the imaging section.

A system and method include a shaker configured to separate solids from a drilling fluid, the shaker having a screen assembly, and an actuated arm operatively coupled to the shaker, the actuated arm configured to interact with the screen assembly of the shaker. The actuated arm is configured to interact with the screen assembly of the shaker, with the actuated arm configured to remove, to inspect, to clean, to repair, or to replace the screen assembly of the shaker.

A system includes a plurality of semiconductor processing tools; a carrier purge station; a carrier repair station; and an overhead transport (OHT) loop for transporting one or more substrate carriers among the plurality of semiconductor processing tools, the carrier purge station, and the carrier repair station. The carrier purge station is configured to receive a substrate carrier from one of the plurality of semiconductor processing tools, purge the substrate carrier with an inert gas, and determine if the substrate carrier needs repair. The carrier repair station is configured to receive a substrate carrier to be repaired and replace one or more parts in the substrate carrier.

A tire mounting method is provided for automatically mounting a tire onto hub bolts of a motor vehicle. The method includes gripping the tire and temporarily tightening nuts on the hub bolts on which the tire has been placed with a first working mechanism. The nuts that have been temporarily tightened by the first working mechanism are fully tightened with a second working mechanism, which is disposed in association with a first mounting region on a front wheel side or on a rear wheel side of the motor vehicle. The nuts that have been temporarily tightened by the first working mechanism are fully tightened with a third working mechanism, which is disposed in association with a second mounting region on the rear wheel side or on the front wheel side of the motor vehicle.

A tire mounting apparatus is constructed from a first working mechanism and a second working mechanism that are separate from each other. The first working mechanism is provided with a tire holding device for holding a tire and with a temporary tightening device for temporarily tightening nuts onto hub bolts to which the tire is mounted. The second working mechanism is provided with a final tightening device means for finally tightening the temporarily tightened nuts. The final tightening device includes two nut runners and an interval adjuster for adjusting an interval between the two nut runners.

A cable bushing fitting machine includes: a fitting region; a mandrel disposed at said fitting region, said mandrel being hollow to receive a cable therethrough; a first rotatably mounted stripping jaw arranged in the fitting region; a second rotatably mounted stripping jaw arranged in the fitting region; a drive configured to mount cable bushings onto cable by successively disposing respective ones of the cable bushings onto the mandrel, feeding the cable through the mandrel, and executing a relative movement between the mandrel and the first and second rotatably mounted stripping jaws to locate the respective cable bushings onto the cable; a camera directed toward the fitting region to capture images of the respective cable bushings located on the cable; and at least the first rotatably mounted stripping jaw having a rotation axis, the first stripping jaw rotation axis being laterally offset from an optical axis of said camera by a distance sufficient to permit the camera unimpeded views of cable bushings in the fitting region when the first stripping jaw is at least to a first selected extent opened.