A support pin arrangement determination assisting method includes: displaying an image including a board image that indicates a shape and an arrangement of an already mounted component on an already mounted surface; inputting an arrangement position of a support pin to the displayed image; superimposing a pin arrangement image indicating the input arrangement position on the board image to create a composite image; and displaying the composite image. The composite image, a first pin arrangement image, and a second pin arrangement image are superimposed on the board image. The first pin arrangement image is generated by inputting an arrangement position in a state that the board is positioned at the first mounting work position, and the second pin arrangement image is generated on the basis of the first pin arrangement image with an assumption that the board is positioned at the second mounting work position.

A data center includes various sets of infrastructure modules which each provide a particular type of infrastructure support to support computing operations in the data center. Separate sets of infrastructure modules can be installed incrementally based on incrementally changing support capacity for the corresponding type of infrastructure support in the data center. Such incrementally changing support capacity can be based upon support requirements of electrical loads, including rack computer systems, which are inbound to the data center. Where support capacity for a particular type of infrastructure support drops below a threshold, a quantity of additional infrastructure modules which provide the particular type of infrastructure support can be selected and installed to increase the support capacity. Separate sets of infrastructure modules can be selected and installed independently of each other, to independently adjust support capacity for separate types of infrastructure support, which can minimize excess support capacity at any given time.

Embodiments include systems, methods, and apparatuses for providing a portable upright stand. A portable upright stand can include a pole for suspending objects such as string lighting, protective coverings, etc. The pole can be coupled to a base such that electrical wiring may extend through the pole and the base. The portable upright stand can also include a reservoir that can enclose at least a portion of the pole such that the pole can be stabilized by the reservoir. The reservoir can have a first opening for filling the reservoir with water and a second opening for draining water. The portable upright stand can also have a shell that can be configured to surround the reservoir as decor or as a protective covering.

A panel for an electromagnetic shield includes a light-weight, porous, electrically-conductive core layer of metallic foam having generally parallel opposed surfaces and a face sheet having rigidity properties superior to the rigidity properties of the core layer laminated to a surface of the core layer. Alternatively, a panel for a broadband electromagnetic shield includes a composite fiber-reinforced core having opposed surfaces and a layered electrically-conductive composite cover disposed on a surface of the core. The cover includes a first stratum of porous metal exhibiting pronounced low-frequency electromagnetic shielding properties and a second stratum of electrically-conductive elements exhibiting pronounced high-frequency electromagnetic shielding properties secured in an overlapping electrically-continuous relationship to the first stratum, the first stratum being a metallic lattice, and the electrically-conductive elements being a non-woven veil of electrically-nonconductive metal-coated fibers.

A data center rack allocation system allocates rack computer systems to be installed at particular rack positions based at least in part upon correlating infrastructure support requirements of the rack computer systems with infrastructure support capacities associated with the rack position. Such allocation can enable rapid incremental deployment of infrastructure and rack computer systems in a data center with flexibility to allocate various types of rack computer systems, with various support requirements, to available infrastructure. The system can identify infrastructure connections available to provide certain types of support capacity and can associate such connections with various rack positions in data centers. The system can determine the support requirements of a rack computer system in response to a determination that the rack computer system is presently inbound for delivery to a data center. The system can allocate particular infrastructure connections to a rack computer system allocated to a rack position.

A twist-and-lock mounting bracket secures a lighting fixture to a mounting surface. The twist-and-lock mounting bracket defines an aperture having features corresponding to the shape of a twist-and-lock element disposed on a housing of a lighting fixture. Accordingly, the twist-and-lock element is configured to extend through the aperture while the corresponding features of the twist-and-lock element and the aperture are aligned. The housing may then be rotated such that the tabs do not align with the corresponding features of the aperture, and the twist-and-lock element is thereby prevented from sliding through the aperture. The mounting bracket may be secured to a junction box positioned within a mounting surface, or it may be secured to a biasing bracket having one or more second resilient members configured to engage the interior of a recessed can light.

A method of forming a terminating end of a cable, comprising the steps of: providing a cable; cutting a circumferential slit through an outer insulation layer; clamping a first section of the outer insulation layer with a first clamping device, and clamping a second section of the outer insulation layer with a second clamping device; displacing the first clamping device, separating the first section from the second section and exposing a section of a metal braid; displacing the first clamping device; pushing and pressing the exposed section to fold the exposed section into a braid protrusion portion; loosening the first and second clamping devices, and removing the cable from the first and second clamping devices; cutting the braid protrusion portion with a cutting device to form a protruding braid portion, the protruding braid portion; and removing the first section of the outer insulation layer and a first protruding braid portion.

A method in the manufacturing of an insulated electric high voltage DC termination or joint includes the steps of providing an insulated electric high voltage DC cable including an inner conductor; a polymer based insulation system, the polymer based insulation system comprising an insulation layer and a semiconducting layer; and an outer grounding layer; removing the grounding layer and the semiconducting layer in at least one end portion of the high voltage DC cable, thereby exposing the insulation layer in the at least one end portion of the high voltage DC cable; covering the insulation layer of the polymer based insulation system in the at least one end portion of the high voltage DC cable by a cover impermeable to at least one substance present in the insulation layer of the polymer based insulation system in the at least one end portion of the high voltage DC cable in a non-homogenous distribution; subjecting the insulation layer of the polymer based insulation system in the at least one end portion of the high voltage DC cable for a heat treatment procedure, while being covered by the cover, thereby equalizing the concentration of the at least one substance in the insulation layer of the polymer based insulation system in the at least one end portion of the high voltage DC cable; and removing the cover. Instead of using a temporary cover, which is later removed, as the impermeable barrier, a field grading adapter or joint body mounted at the end of the DC cable during the manufacturing of the high voltage DC termination or joint may be used.

A method in the manufacturing of an insulated electric high voltage DC termination or joint includes providing an insulated electric high voltage DC cable including a high voltage DC conductor, a polymer based insulation system surrounding the high voltage DC conductor, the polymer based insulation system including an insulation layer and a semiconducting layer surrounding the insulation layer, and a grounding layer surrounding the semiconducting layer, removing the grounding layer and the semiconducting layer in at least one end portion of the high voltage DC cable, thereby exposing the insulation layer of the polymer based insulation system in the at least one end portion of the high voltage DC cable, mounting a field grading adapter or joint body in the at least one end portion of the high voltage DC cable, thereby covering the insulation layer of the polymer based insulation system in the at least one end portion of the high voltage DC cable, the field grading adapter or joint body being part of the high voltage DC termination or joint, wherein at least one substance is present in the insulation layer of the polymer based insulation system in the at least one end portion of the high voltage DC cable in a non-homogenous distribution; and subjecting the insulation layer of the polymer based insulation system in the at least one end portion of the high voltage DC cable for a heat treatment procedure, while being covered by the mounted field grading adapter or joint body, thereby equalizing the concentration of the at least one substance in the insulation layer of the polymer based insulation system in the at least one end portion of the high voltage DC cable.

Disclosed herein are embodiments of beds and components thereof. In one embodiment, a bed comprises a frame; a plurality of adjustable members, each coupled to the frame, and each of the plurality of adjustable members adjustable to individual positions; one or more sensors coupled to one or more of the adjustable members; and a controller, the controller configured for receiving input from the one or more sensors and determining at least one adjusted sleep setting for the occupant. The controller is further configured to control the plurality of adjustable members and adjust each of the plurality of adjustable members according to the at least one adjusted sleep setting. The adjustable members may comprise struts, slats, or a combination thereof.