An electronic device is provided. The electronic device includes a display including a display area and a connecting area extending from one side of the display area, a flexible printed circuit board (FPCB) connected with the connecting area, and a first module mounted on a first surface of the FPCB, where the connecting area is bent such that the first module is apart from the display to face the display.

Methods, systems, devices, and products for manufacturing an electrical assembly, such as a completed downhole circuit board, for use in well logging. Methods include attaching an electrical component to a printed circuit board by mechanically fastening the electrical component to the printed circuit board. Methods may include using a laser to attach a plurality of legs to contact surfaces. Methods may include applying light from the laser to a material of the printed circuit board to produce heat, including mitigating reflection of the light from the material. Methods include forming a connection between a first electrical component of the electrical assembly and a second electrical component of the electrical assembly by causing heating of an additive manufacturing material by applying light from a laser. The connection may be at least one of: i) an electrical connection; ii) a structural connection; iii) an electrical insulation.

A shock resistant fuselage system includes first and second fuselage side walls, each of the first and second fuselage side walls having a plurality of guide posts, and a printed circuit board (PCB) rigidly attached to at least one of the first and second fuselage side walls, the PCB having a plurality of guide slots, each of the plurality of guide posts slideably seated in a respective one of the plurality of guide slots so that elastic deformation of the PCB is guided by the guide slots between the first and second fuselage side walls.

An electronic component (E), including at least one circuit carrier (1), which is populated with a number of mechanical and/or electronic component parts (2 to 4) and has at least one contact opening (1.3) for forming a mechanical and/or electrical contact-connection point (KS) to at least one of the component parts (2 to 4), wherein at least one of the component parts (4) is at a distance from the circuit carrier (1), includes at least one electrically conductive housing (4.1) and at least one electrical contact element (4.2) projecting out of the housing (4.1), the contact element being insulated from the housing (4.1) and being connected at least in a materially bonded manner to the contact opening (1.3) of the circuit carrier (1), wherein at least one seal element (5) is arranged in the region of the contact-connection point (KS), in particular between the circuit carrier (1) and the housing (4) of the component part (4).

A solder component includes one or more terminal members each having a bending portion bending in a direction crossing a surface of a substrate and being connected to the surface of the substrate, and four or more substrate connection portions formed at end portions of the terminal members, three substrate connection portions out of the four or more substrate connection portions each having a width narrower than a width of the bending portion of the corresponding terminal member, when the solder component is disposed on the surface of the substrate, only the three substrate connection portions being in contact with the surface of the substrate, and no matter where a contact point contacting the surface of the substrate is provided on each substrate connection portion, a mass center of the solder component being located inside a triangle determined by three contact points of the three substrate connection portions.

A surface mount (SMD) diode taking a runner as the body and a manufacturing method thereof are described. An elongated runner groove is adopted to cure and package groups of diode chips arranged side by side and corresponding copper pins thereon, with the utilization rate of epoxy resin up to 90% or more. The use cost of epoxy resin is thus reduced, and environmental pollution is also reduced.

A solder component includes one or more terminal members each having a bending portion bending in a direction crossing a surface of a substrate and being connected to the surface of the substrate, and four or more substrate connection portions formed at end portions of the terminal members, three substrate connection portions out of the four or more substrate connection portions each having a width narrower than a width of the bending portion of the corresponding terminal member, when the solder component is disposed on the surface of the substrate, only the three substrate connection portions being in contact with the surface of the substrate, and no matter where a contact point contacting the surface of the substrate is provided on each substrate connection portion, a mass center of the solder component being located inside a triangle determined by three contact points of the three substrate connection portions.

A method of attaching a contact element to a conductor plate includes welding the contact element to a conductive path of the conductor plate in a surface-mounted manner with a laser beam.

A retainer device which connects to a printed circuit board (PCB) to provide added structural rigidity to a capacitor (or other electrical component) mounted to the PCB. The retainer device is able to provide increased durability of capacitor leads against vibrational fatigue. The retainer device is designed to add structural rigidity to single or multiple capacitors soldered to a PCB. The retainer device exerts a positive force against the capacitor, pressing the capacitor against the PCB. This in turn limits the fatigue deflection of the capacitor leads. The retainer device has at least one spring retention ring, where the spring retention ring is able to apply force to the capacitor, which aids in ensuring that the capacitor is flush to the surface of the PCB, which reduces the load on the leads of the capacitor.

PROBLEM TO BE SOLVED: To provide a laser jointing method that joints two materials while imparting a sufficient strength thereto and minimizing heat influence. SOLUTION: The method overlaps first and second materials (V1, V2) on each other and irradiates the surface of the first material (V1) with a laser light (103) from the side of the first material (V1). When jointing both materials (V1, V2), the method intermittently irradiating an overlapped part of the first and second materials (V1, V2) with the laser light while moving the laser light (103) to form a welding bead (1) on the surface of the first material (V1), wherein the length of the welding bead (1) is formed gradually shorter.