A sensor unit includes a circuit board including, on a first surface, a plurality of electrode pads to which a plurality of mounting terminals of an inertial sensor are respectively attached via connecting members. The first surface of the circuit board includes an insulating layer provided on the outer side of the plurality of electrode pads in a plan view, includes, in a portion overlapping a center region further on the inner side than the mounting terminals of the inertial sensor in the plan view, a first region where the insulating layer is not provided, and includes, from the first region to the outer side of the inertial sensor in the plan view, a second region where the insulating layer is not provided.

A glider tool can be provided for installing a back panel of an enclosure. The glider tool can include a body having a first surface, a second surface opposite the first surface, a first end, and a second end opposite the first end, the body defining a length that extends from the first end to the second end. The first end of the body can be configured to engage a front frame member of the enclosure, and the second end of the body can be configured to contact the enclosure, when the glider tool is in an installed configuration.

A screw starting device is provided. The screw starting device includes a body, an adjustment assembly and a screw holder. The body includes a screw holding portion and an indexing surface. The adjustment assembly is integral with the screw holding portion. The screw holder is removably attachable to the adjustment assembly. The screw holder includes an insert selected from a group of inserts respectively compatible with screws of varying types. The adjustment assembly is operable to adjust a location of the screw holder relative to the indexing surface.

Embodiments are provided that enable an implantable connector, along with related apparatuses, devices, systems, methods, computing devices, computing entities, and/or the like to serve patients with neural interfaces requiring connectors with higher channel densities (>0.05 ch/mm.sup.3) or higher channel counts (>32) than is practical with conventional implant-connector technology.

A flexible electrical system distribution, switching, and protection solution having two or more autonomous electrical switching devices and optionally adding circuit protection and manual switching in one self-contained device. A printed circuit board assembly is configured to operate two or more electrical switch functions to act from a remote signal input or autonomously, independently or simultaneously. The printed circuit board can be assembled into a housing where multiple independent circuits on the printed circuit board assembly can be permanently electrically connected to each other through electrical conductors thus reducing the number of independent circuits within the assembly. The assembly further consists of an electrically isolative housing and terminal studs and retaining nuts capable to receiving electrical cable ring terminals.

Explosion-proof pressure-resistant housing with a receiving part for electric operating components and with a closure part that closes the receiving part via a bayonet catch, wherein the closure part has a cylindrical segment that forms a flameproof joint when inserted into the receiving part, the cylindrical segment of the closure part has pins and the cylindrical outer wall of the receiving part contains longitudinal slots, at the ends of which longitudinal slots short transverse slots connect for receiving the pins, where a locking part is slid onto the closure part and includes locking elements distributed across the periphery and engaging in the longitudinal slots such that the pins are prevented from rotating out of the transverse slots, and where the locking part is fastened to the closure part via at least one fastener that detachable exclusively via a tool.

A data storage device includes an enclosure and a Printed Circuit Board Assembly (PCBA) extending in a basal plane, and a plurality of semiconductor memory packages electromechanically bonded to the PCBA and coupled to the enclosure with thermal interface material. The data storage device further includes a first fitting coupled to a first end of the PCBA and the enclosure, restricting movement of the PCBA in the basal plane with respect to the enclosure and restricting movement of the PCBA out of the basal plane. The data storage device further includes a second fitting coupled to a second end of the PCBA, allowing movement of the PCBA in the basal plane with respect to the enclosure and restricting movement of the PCBA out of the basal plane.

A data center cabinet has an equipment rail movably secured to front-to-back beams by a retaining mechanism. The retaining mechanism has a threaded member extending through a front-to-back beam and the equipment rail and a handle rotatable relative to the threaded member. A first cam disk is positioned between the handle and equipment rail and is fixed to the equipment rail and a second cam disk is positioned between the handle and first cam disk and is fixed to the handle. First and second surfaces of the first and second cam disks are engaged with the handle in a first position to provide a clamping force between the equipment rail and front-to-back beam to prevent movement of the equipment rail and the first and second cam surfaces are disengaged with the handle in a second position to remove the clamping force to allow movement of the equipment rail.

A data center cabinet has a base frame with a pair of front vertical posts, first bottom and top side-to-side beams connected to the front vertical posts, a pair of back vertical posts, second bottom and top side-to-side beams connected to the back vertical posts, and front-to-back beams connecting the front vertical posts and back vertical posts. The first and second bottom side-to-side beams each comprise an opening configured to allow a removable transport caster to pass through the opening, a first set of keyholes configured to receive and retain a set of mounting buttons of a first removable transport caster, and a second set of keyholes configured to receive and retain a set of mounting buttons of a second removable transport caster.

In general, one aspect of the subject matter described in this specification can be embodied in an anti-fogging apparatus for a camera assembly. The anti-fogging apparatus includes a camera affixed to a substrate, and a thermally conductive plate, the thermally conductive plate positioned in front of the substrate and defining a first aperture aligned with a lens of the camera. The anti-fogging apparatus includes a transparent plate positioned in front of the thermally conductive plate such that the transparent plate covers said first aperture. The anti-fogging apparatus includes an insulating element positioned in front of the transparent plate and defining a second aperture aligned with the first aperture. The anti-fogging apparatus includes a heating element affixed to the thermally conductive plate. The anti-fogging apparatus includes a case enclosing the camera, the thermally conductive plate, the transparent plate, the insulating element, and the heating element.