Abstract: A sensor assembly includes a sensor including a sensor lens, a casing mounted to the sensor, and a fluid nozzle mounted to the casing. The casing at least partially defines a duct positioned to outlet airflow across the sensor lens, and the duct defines a direction of airflow. The fluid nozzle is aimed through the duct in the direction of airflow.

Abstract: A sensor assembly includes a first sensing device and a second sensing device spaced from the first sensing device. The sensor assembly includes a bracket supporting the first sensing device and the second sensing device and a sensor cover including a first sensor window and a second sensor window. The first sensing device has a first field of view through the first sensor window and the second sensing device having a second field of view through the second sensor window. The sensor assembly includes an air nozzle housing supported by the bracket and defining a first air nozzle aimed toward the first sensor window and a second air nozzle aimed toward the second sensor window. The sensor assembly includes a washer nozzle spaced from the first air nozzle. The washer nozzle aimed toward the first sensor window in a direction opposite to a direction of the first air nozzle.

Abstract: A vehicle includes a window; a sensor housing including an air inlet, a first air outlet, and a second air outlet; an image sensor supported by the sensor housing; and a blower positioned to draw in air through the air inlet and expel the air through the first air outlet and the second air outlet. The first air outlet is aimed at the image sensor, and the second air outlet is aimed at the window.

Abstract: A sensor assembly includes a sensor including a sensor lens, the sensor lens defining an axis; a housing panel including an aperture centered on the axis, the sensor lens being recessed from the aperture along the axis; and an air nozzle positioned between the aperture and the sensor lens along the axis and oriented to blow horizontally across the sensor lens. The aperture and the sensor lens define a gap positioned on an opposite lateral side of the sensor lens from the air nozzle.

Abstract: A sensor assembly includes a first sensing device and a second sensing device spaced from the first sensing device. The sensor assembly includes a bracket supporting the first sensing device and the second sensing device and a sensor cover including a first sensor window and a second sensor window. The first sensing device has a first field of view through the first sensor window and the second sensing device having a second field of view through the second sensor window. The sensor assembly includes an air nozzle housing supported by the bracket and defining a first air nozzle aimed toward the first sensor window and a second air nozzle aimed toward the second sensor window. The sensor assembly includes a washer nozzle spaced from the first air nozzle. The washer nozzle aimed toward the first sensor window in a direction opposite to a direction of the first air nozzle.

Abstract: A sensor assembly includes a sensor including a cylindrical sensor window defining an axis, a cover fixed relative to the sensor, and a duct mounted to the sensor and extending through the axis. The cover is positioned to expose a circumferential portion of the sensor window. The circumferential portion extends circumferentially relative to the axis from a first end adjacent to the cover to a second end adjacent to the cover. The circumferential portion includes a midpoint circumferentially between the first end and the second end. The duct includes an inlet and an outlet. The outlet extends circumferentially from the first end of the circumferential portion to the second end of the circumferential portion. The duct includes a deflector positioned to direct airflow from the inlet to the outlet at the first end and second end of the circumferential portion before the airflow reaches the midpoint of the circumferential portion.

Abstract: A sensor assembly includes a housing defining a chamber. A sensor is disposed in the chamber and has a lens. An air nozzle is aimed to direct air across the lens. A blower is disposed in the chamber and in fluid communication with the air nozzle. A velocity stack is mounted to the blower and includes an air foil and an outer wall spaced from the air foil and extending entirely around the air foil. The air foil and the outer wall define a channel therebetween. The blower is in fluid communication with the chamber through the channel.

Abstract: A sensor assembly includes a sensor including a sensor lens, a casing mounted to the sensor, and a fluid nozzle mounted to the casing. The casing at least partially defines a duct positioned to outlet airflow across the sensor lens, and the duct defines a direction of airflow. The fluid nozzle is aimed through the duct in the direction of airflow.

Abstract: An assembly includes a liftgate and an autonomous navigation sensor assembly supported by the liftgate. The autonomous navigation sensor assembly has a plurality of sensors and a vent facing across a field-of-view of one of the sensors.

Abstract: An assembly includes a liftgate and an autonomous navigation sensor assembly supported by the liftgate. The autonomous navigation sensor assembly has a plurality of sensors and a vent facing across a field-of-view of one of the sensors.

Abstract: Various embodiments relate generally to electrodynamic machines and the like, and more particularly, to rotor assemblies and rotor-stator structures for electrodynamic machines, including, but not limited to, outer rotor assemblies and/or inner rotor assemblies with a corresponding stator assembly. In some embodiments a rotor assembly can include magnetically permeable structures having confronting surfaces oriented at an angle to the axis of rotation. A group of magnetic structures can be interleaved with the magnetically permeable structures. The magnetically permeable structures can also include non-confronting surfaces adjacent to which boost magnets are disposed to enhance flux in a flux path passing through magnetic structures that are interleaved with magnetically permeable structures. Further, the rotor assemblies can include a flux conductor shield disposed adjacent to the boost magnets, the flux conductor shield configured to provide return flux paths.

Abstract: Various embodiments relate generally to electrodynamic machines and the like, and more particularly, to rotor assemblies and rotor-stator structures for electrodynamic machines, including, but not limited to, outer rotor assemblies. In some embodiments, a stator assembly including field pole members arranged about an axis of rotation and including pole faces at the ends of the field pole members, subsets of the pole faces being disposed within a boundaries of conically-shaped spaces having apexes disposed on the axis of rotation. The rotor assemblies include interior regions in which the subsets of the pole faces are disposed, the interior regions having surfaces external to the boundaries of the conically-shaped spaces. The rotor assemblies also include subsets of magnets interleaved circumferentially with the subsets of magnetically permeable structures and boost magnets disposed adjacent the subsets of magnetically permeable structures.

Abstract: Various embodiments relate generally to electrodynamic machines and the like, and more particularly, to rotor assemblies and rotor-stator structures for electrodynamic machines, including, but not limited to, outer rotor assemblies and/or inner rotor assemblies with a corresponding stator assembly. In some embodiments a rotor assembly can include magnetically permeable structures having confronting surfaces oriented at an angle to the axis of rotation. A group of magnetic structures can be interleaved with the magnetically permeable structures. The magnetically permeable structures can also include non-confronting surfaces adjacent to which boost magnets are disposed to enhance flux in a flux path passing through magnetic structures that are interleaved with magnetically permeable structures. Further, the rotor assemblies can include a flux conductor shield disposed adjacent to the boost magnets, the flux conductor shield configured to provide return flux paths.

Abstract: Various embodiments relate generally to electrodynamic machines and the like, and more particularly, to rotor assemblies and rotor-stator structures for electrodynamic machines, including, but not limited to, outer rotor assemblies. In some embodiments, a stator assembly including field pole members arranged about an axis of rotation and including pole faces at the ends of the field pole members, subsets of the pole faces being disposed within a boundaries of conically-shaped spaces having apexes disposed on the axis of rotation. The rotor assemblies include interior regions in which the subsets of the pole faces are disposed, the interior regions having surfaces external to the boundaries of the conically-shaped spaces. The rotor assemblies also include subsets of magnets interleaved circumferentially with the subsets of magnetically permeable structures and boost magnets disposed adjacent the subsets of magnetically permeable structures.

Abstract: Various embodiments relate generally to electrodynamic machines and the like, and more particularly, to rotor assemblies and rotor-stator structures for electrodynamic machines, including, but not limited to, outer rotor assemblies and/or inner rotor assemblies. In some embodiments, a rotor-stator structure includes a rotor structure in which rotor assemblies are arranged on an axis of rotation. A rotor assembly can include an arrangement of magnetic regions each having a portion of a surface that is oriented substantially at an angle to the axis and disposed externally to, for example, a portion of a conically-shaped space centered on the axis of rotation. The rotor-stator structure also can include pole members (e.g., field pole members) having pole faces. A subset of the pole faces can be positioned to confront the arrangement of the magnetic regions to establish air gaps, with the subset of the pole faces being disposed internally to the conically-shaped space.

Abstract: Embodiments of various rotor assemblies can include an arrangement of magnetically permeable structures including confronting surfaces oriented at an angle to the centerline, and different subsets of non-confronting surfaces. Different magnets can be disposed adjacent to the different subsets of non-confronting subsets. For example, one type of magnet lies is a flux path or a flux path portion passing through one subset of non-confronting surfaces, and another type of magnet is external to the flux path adjacent to another subset of non-confronting surfaces and is configured to boost the flux associated with the flux path (or a portion thereof). In some embodiments, the magnetic region can include a portion of the internal permanent magnet. One example of a rotor assembly is an outer rotor assembly.

Abstract: An end-effector that loads disks into a pallet of a sputtering machine, for example, has a two-piece mandrel with a rigid inner core and a plastic outer sleeve slideably axially mounted on the core. The sleeve is attached to the core with a coupling providing a predetermined attachment force. A breakaway force exerted on the sleeve that exceeds the attachment force causes the sleeve to separate from the mandrel, this separation being sensed by a breakaway sensor.

Abstract: An end-effector that loads disks into a pallet of a sputtering machine, for example, has a two-piece mandrel with a rigid inner core and a plastic outer sleeve slideably axially mounted on the core. The sleeve is attached to the core with a coupling providing a predetermined attachment force. A breakaway force exerted on the sleeve that exceeds the attachment force causes the sleeve to separate from the mandrel, this separation being sensed by a breakaway sensor.

Abstract: A fluid dispensing apparatus is mounted to and supported by any of numerous sizes and styles of bicycles. The fluid dispensing apparatus has a means for storing water, a means for pressurizing stored water, a means for controlling the release of pressurized water in the form of a plurality of high velocity water jets, a means for independently aiming said water jets, a means for conducting fluid between components, and a means for mounting components to the frame of a bicycle. One embodiment of the invention incorporates one or a plurality of serially connected pressurized water reservoir assemblies (28), a dual piston-in-cylinder water pump assembly (24), a manually operated water pump lever assembly (22), an assembly (26) of multiple independent, manually-activated triggers, and multiple independently aimable nozzles (160, 190). The reservoir, pump, and trigger assemblies are mounted to and supported by frame members (20a, 20b, 20c, 20d) of the bicycle.