A resistor support assembly includes first, second, third, and fourth support members. Each of the first and second support members includes one or more resistor contact regions and apertures extending therethrough. Each third support member is at least partially disposed within one of the apertures of one of the first support members and one of the apertures of one of the second support members. Recesses may be formed in the resistor contact regions of the first and the second support members, and one or more load resistors may be at least partially disposed within the recesses. The resistor support assembly may be used to mount one or more load resistors to a printed circuit board, without obstructing airflow through hollow portions of the load resistors. To reduce parasitic capacitance and inductance, the first support members and the second support members are formed from non-conductive materials.

Provided is an LED lamp using a nano-scale LED electrode assembly. The LED lamp using the nano-scale LED electrode assembly may solve limitations in which, when a nano-scale LED device according to the related art stands up and is three-dimensionally coupled to an electrode, it is difficult to allow the nano-scale LED device to stand up, and when the nano-scale LED devices are coupled to one-to-one correspond to electrodes different from each other, product quality is deteriorated. Thus, the nano-scale LED device having a nano unit may be connected to the two electrodes different from each other without causing defects, and light extraction efficiency may be improved due to the directivity of the nano-scale LED devices connected to the electrodes. Furthermore, deterioration in function of the LED lamp due to the defects of a portion of the nano-scale LEDs provided in the LED lamp may be minimized, and the LED lamp may have a flexible structure and shape by using the nano-scale LED electrode assembly of which a portion is deformable according to the used purpose or position of the LED lamp.

A mounting structure for an electronic component and a method for mounting the electronic component are provided with a sufficient reinforcing effect for the relatively tall electronic component raised from a substrate. The mounting structure and the mounting method can easily respond to a change of the shape of the electronic component. In a mounting structure 1, a substrate 2 and an electronic component 4 raised on the substrate 2 are joined with bonding metal 3 and a reinforcing resin body 5 is bonded to the substrate 2 and the electronic component 4. The reinforcing resin body 5 includes a plurality of reinforcing resin layers 5a. The reinforcing resin layers 5a constituting the reinforcing resin body 5 are stacked in the height direction of the raised electronic component 4 along a side 4a of the electronic component 4 so as to be raised from the substrate 2.

A streamlined battery pack can contain at least two battery cells. A printed circuit board (PCB) of the battery pack can include a protection control module. The PCB can have castellations along its perimeter in which wires are soldered. The wires can include battery power wires and battery monitoring signal wires. The castellations are sized so that the egress wires can be soldered therein without substantially protruding from the outline of the PCB. The PCB has a surface area that is no greater than an end of the battery pack, and thereby need not exceed the outer diameter of the remainder of the battery pack. The PCB and the other battery pack components may be substantially enveloped in a polyimide material. The components of the battery pack, including the PCB can arranged, sized and configured, such that they do not create protuberances in the enveloping material.

A laterally placed capacitor package assembly and an assembly method thereof are provided. The laterally placed capacitor package assembly includes a wound capacitor package structure and a capacitor supporting structure. The wound capacitor package structure includes a wound assembly, a conductive assembly and a package assembly. The conductive assembly includes a first conductive pin and a second conductive pin. The capacitor supporting structure includes a supporting portion configured to support the wound capacitor package structure and a plurality of positioning portions extending outward from the supporting portion. When the laterally placed capacitor package assembly is configured to be laterally disposed on a circuit substrate, a first exposed portion of the first conductive pin and a second exposed portion of the second conductive pin can be laterally and electrically connected to the circuit substrate without bending.

An electrical device can include a body having a shape and including one or more components, and first and second electrodes implemented at respective locations of the body and configured to provide first and second engagements with a mounting surface and to allow a settling motion when the electrical device is positioned on the mounting surface. The electrical device can further include a third electrode implemented at a respective location of the body and configured to allow a limited range of the settling motion such that at an end of the limited range of the settling motion, the third electrode provides a third engagement with the mounting surface.

A circuit board includes a plurality of circuit board layers arranged one on top of the other, wherein through-holes are integrated in the circuit board, wherein the through-holes are configured to receive metal screws that screw the circuit board to a heat sink. Insulating sleeves made of an insulating material are integrated into the circuit board, wherein the through-holes are formed in the circuit board in the region of the insulating sleeves.

A resistor support assembly includes first, second, third, and fourth support members. Each of the first and second support members includes one or more resistor contact regions and apertures extending therethrough. Each third support member is at least partially disposed within one of the apertures of one of the first support members and one of the apertures of one of the second support members. Recesses may be formed in the resistor contact regions of the first and the second support members, and one or more load resistors may be at least partially disposed within the recesses. The resistor support assembly may be used to mount one or more load resistors to a printed circuit board, without obstructing airflow through hollow portions of the load resistors. To reduce parasitic capacitance and inductance, the first support members and the second support members are formed from non-conductive materials.

A capacitor holder comprises: a holding portion having a cylindrical inner wall surface, at least an outer peripheral portion of the inner wall surface being open, the holding portion being configured to hold a capacitor inserted through the opening into an inside of the inner wall surface; a fixed portion formed integrally with the holding portion and positioned opposite to the opening of the holding portion; a pair of fitting grooves formed at a pair of end surfaces of the fixed portion opposed to each other adjacent to the holding portion, the fitting grooves being configured to fittably engage with end edges of a printed circuit board to extend along a surface of the printed circuit board; and a proximity suppressor configured to suppress portions of the fixed portion where the fitting grooves are formed from being brought into proximity each other.

A wiring board includes an insulating layer having a first surface and a second surface, which are opposite to each other, upper wiring patterns on the first surface of the insulating layer, lower wiring patterns on the second surface of the insulating layer, intermediate wiring patterns, which are disposed in the insulating layer and are electrically connected to the upper wiring patterns and the lower wiring patterns, and a capacitor wire connected to corresponding wiring patterns of the upper wiring patterns, the lower wiring patterns, and the intermediate wiring patterns. The capacitor wire includes a core electrode line having a wire shape, an outer electrode line covering at least a portion of the core electrode line, and a dielectric line interposed between the core electrode line and the outer electrode line.