An electronic device for an aircraft includes: a casing; a first boss projecting from a bottom wall of the casing toward an opening of the casing; a second boss projecting from the bottom wall of the casing toward the opening of the casing by a larger amount than the first boss; a first circuit board fixed to the first boss; and a second circuit board fixed to the second boss. The first circuit board includes cutouts penetrated by the second boss when the first circuit board is fixed to the first boss.

A power supply device is disclosed. A circuit board is disposed inside a conductive housing. A rectifying module is disposed on the circuit board and has primary and secondary sides. The grounding module includes a first grounding element, a second grounding element, and a fastening element. Two terminals of the first surge protection module are respectively electrically connected to the primary side and the first grounding element. Two terminals of the second surge protection module are respectively electrically connected to the secondary side and the second grounding element. The second grounding element and the first grounding element are not directly connected. The fastening element passes through the conductive housing, the circuit board, the first grounding element, and the second grounding element so that the conductive housing, the first grounding element, and the second grounding element are electrically connected to one another.

A multiple board standoff for interconnecting a plurality of electronic boards, such as printed circuit boards, having at least one keyhole slot. The standoff comprises a plurality of major diameter portions, a plurality of minor diameter portions each disposed between two of the plurality of major diameter portions, and a plurality of abutment surfaces each transversely extending from one of the major diameter portions to one of the minor diameter portions. At least one of the minor diameter portions is configured to be inserted into the keyhole slot when the standoff is in a first orientation with respect to the electronic board and being retained within the keyhole slot when the standoff is in a second orientation with respect to the electronic board.

An electrical junction box can include a case, a substrate connector, and a substrate. The substrate is temporarily fixed and soldered to the substrate connector. The substrate connector and the substrate are stored in the case. The substrate connector includes a pair of shaft-shaped temporary fixing protrusions. Each of the temporary fixing protrusions includes a positioning shaft that positions the substrate and a temporary fixing shaft that prevents the temporary fixing protrusions from coming loose from the substrate. The temporary fixing protrusions can be fitted into fitting holes in the substrate.

Printed circuit boards (PCBs) are configured with an athermalized mounting suitable for securing and positioning and the PCBs within an inertial measurement unit (IMU). The PCBs include integrated circuit (IC) components, such as accelerometers and/or gyroscopes, which require relative positional stability within the IMU environment in order to provide accurate results. The athermalized mounting configuration of the PCB enables the PCBs to experience thermal expansion within the IMU without causing significant displacement of the IC relative to the IMU environment.

A fastening device includes at least one base portion and at least one fastener portion. The base portion is connected to a first object and the fastener portion is slidably assembled to the base portion. The fastener portion cooperates with the base portion to provide a locking and an unlocking function for connecting or disconnecting a second object to or from the base portion. With these arrangements, two objects can be repeatedly and quickly connected to or disconnected from each other.

A housing for receiving electrical and/or electronic components includes a housing base part and a housing cover which covers the housing base part and which is supported on the housing base part and/or fastened to the housing base part at least by a spacer bolt. The housing cover has an opening. The spacer bolt is integrally or substance bonded to an edge of the opening and the spacer bolt closes the opening. An electronic control unit and a method for producing the housing or the control unit are also provided.

A composite module includes a plurality of substrates in a housing, prevents deformation of the stated substrates, and has a characteristic with an improved mounting precision of the substrates within the housing. A wireless LAN module as a composite module according to the present invention includes a first substrate (26), a second substrate (28) that is so disposed as opposed to the other principal surface (48b) of the first substrate (26), and a housing (12) that has accommodation sections (38) and (54) for accommodating the first substrate (26) and the second substrate (28). Further, substrate-support projections for supporting one principal surface and the other principal surface of each of the first substrate (26) and the second substrate (28), are formed on inner wall surfaces (40) and (56) of the accommodation sections (38) and (54) in the housing (12).

A sprung frame assembly that can accommodate varying tolerance device heights while still exerting sufficient pressure/force required to a heatsink to contact and cool a bare die device, or other device of the like. Adapted for space constrained modules where placement of mounting holes is limited, and module density is high. Sprung frames are secured to mounting points at available locations on support structures as to eliminate any mounting holes in the PCB. The required force/pressure can be evenly achieved by methodically tightening a plurality of screws with springs at the corners of the sprung frames in sequence, pressure is applied evenly without damaging the device, while also taking up any tolerances in the device height.

A fitting element includes a first fitting section for connection with a spacer element, and a second arresting section for arresting with a circuit board. A central section is arranged between the fitting section and the arresting section and serves for forming a first stop for the spacer element, and a second stop for the circuit board. The fitting element is connected with an associated spacer element for forming a fitting device. The spacer element is fitted to a first circuit board. A second circuit board is then arrested with the fitting element. In this way two circuit boards can be connected with each other in a simple, flexible and automated way.