A Common Bus Structure for Avionics and Satellites (CBSAS) (10) as shown in FIG. 1 is comprised of a module lid (14), module floor (38), module stack base (16), module compression bolts (22) and stackable modules (12). Stackable modules (12) are sub-dividable to create module scaled chamber volumes (45) individually as required, while stackable modules (12) simultaneously create at least one collectively continuous raceway sealed chamber volume (44) perpendicular to individual stackable modules (12) in the vertical direction where no module floor (38) is present, in order to internally electrically interconnect the contents of any stackable module (12) with the contents of any other stackable module (12) via internal connector raceway system (24). Raceway sealed chamber volume (44) therefore collectively and continuously traverses all present stackable modules (12) positioned between module lid (14) and module stack base (16). Modules are interchangeable and inter-connectable in any order, and contain all required electronic or mechanical components required for CBSAS (10) to function as a single box consolidated avionics system that is equally functional in the atmosphere or the vacuum of space, while also being fully functional as a single complete stand-alone satellite system. CBSAS (10) enables a paradigm shift in the aerospace industry whereby all legacy and current multiple black-box systems on aerospace platforms such as missiles, rockets, satellites and aircraft are extremely inefficient when compared to the size, weight and power attributes of CBSAS (10). The ability for CBSAS (10) to be instantly employable as either a single box consolidated avionics system for use within the atmosphere or in space while also being fully functional as a stand-alone satellite enables a hardware, firmware and software capability never before manifested in the aerospace industry.

The present disclosure provides a hair dryer, the hair dryer including a housing, a switch unit, a controller, a fan unit, and a heating unit, wherein the heating unit is configured such that a non-magnetic field is formed by a first heating coil and a second heating coil being twisted in a shape of a twisted bread stick, where the first heating coil is flowed by a current of first direction and the second heating coil is flowed by a current of second direction opposite to the first direction, at least one of the first coil and the second coil is coated with an insulating shield member, and the first coil and the second coil is wound on a support member in a spiral shape.

An electronic control device includes: a housing accommodating a board on which an electronic component is mounted; and a guard pattern formed on an outer peripheral portion of the board. The guard pattern and a ground pattern of a circuit in the circuit board are connected to each other in a vicinity of an intermediate point of fixed positions where an upper portion of the housing and a lower portion of the housing are fixed to each other.

An embodiment of a power-supply module includes a package having sides, a first power-supply component disposed in the package, and an electromagnetic-interference (EMI) shield disposed adjacent to two sides of the package. For example, such a module may include component-mounting platforms (e.g., a lead frame or printed circuit board) on the top and bottom sides of the module, and these platforms may provide a level of EMI shielding specified for a particular application. Consequently, such a module may provide better EMI shielding than modules with shielding along only one side (e.g., the bottom) of the module. Moreover, if the module components are mounted to, or otherwise thermally coupled to, the shielding platforms, then the module may provide multi-side cooling of the components.

A capacitively-coupled plasma processing apparatus includes: at least one chamber body providing chambers separated from each other; upper electrodes respectively installed in upper spaces within the chambers; lower electrodes respectively installed in lower spaces within the chambers; a high frequency power supply; a transformer including a primary coil electrically connected to the high frequency power supply, and secondary coils each of which coils having a first end and a second end; first condensers respectively connected between each of the first ends of the secondary coils and the upper electrodes; and second condensers respectively connected between each of the second ends of the secondary coils and the lower electrodes. The primary coil extends around a central axis. The secondary coils are configured to be coaxially disposed with respect to the primary coil. A self-inductance of each of the secondary coils is smaller than that of the primary coil.

A shielded conductive path (Wa) includes: a shielding pipe that encloses first and second electrical wires together; a first insertion path that is formed inside the shielding pipe and into which the first electrical wire is inserted; a second insertion path that is formed inside the shielding pipe, is separated from the first insertion path by a partition wall, and into which the second electrical wire is inserted; and a shielding tube that includes at least a portion of a flexible shielding member that is tubular. The shielding tube is connected to an end portion of the first insertion path so as to prevent the first and second electrical wires from being affected by electromagnetic noise therefrom.

A noise current absorber including a pair of housing parts capable of housing each of the pair of magnetic bodies, wherein the pair of magnetic bodies forms an overall cylindrical shape or a ring shape when abutted against each other; an engaging portion and an engaged portion capable of maintaining a closed state of the pair of housing parts; and a wall molded integrally with at least a first housing part of the pair of housing parts, adjacent to an abutting surface of at least the first housing part against a second housing part of the pair of housing parts, the wall protruding to a side where the second housing part abuts.

An apparatus for activating a personal protection arrangement for a vehicle, including a housing, at least one circuit board, and at least one electrical or electronic component, the circuit board having at least one layer for shielding electromagnetic radiation, the circuit board being positioned in the housing in such a way that when the apparatus is mounted in the vehicle, the circuit board shields the electromagnetic radiation that is emitted by the at least one electrical or electronic component at least with respect to the interior of the vehicle. And to a method for manufacturing such an apparatus.

An electronic apparatus including a housing, an electronic component unit main body, an engagement lever, and an engaged member, in which the engagement lever includes a lever main body, an engagement groove, and a restricting member, the lever main body is displaceable between a first state in which the one end portion is inclined to protrude rearward with respect to the other end portion in an insertion direction of the electronic component unit main body with respect to the accommodating part and the engagement groove abuts against the engaged member from the rear in the insertion direction, and a second state in which the lever main body is vertical from the one end portion to the other end portion and the engagement groove engages with the engaged member, and the restricting member is able to restrict the lever main body to being in the second state.

A configurable door panel cover includes a first face of a first door that is perforated and includes one or more attachment points, which one or more configurable panels may attach to. The configurable door panel cover includes a fastener assembly that includes at least one fastener that attaches to the configurable door panel cover, and a spacing mechanism. The spacing mechanism attaches to the fastener that is attached to the configurable door panel cover and to one of the one or more attachment points on the first face of the first door. The spacing mechanism attaches the first configurable door panel cover at a first orientation that includes a first angle between the configurable door panel cover and the first spacing mechanism. The fastener assembly may be rotated to the configurable door panel cover.