Assembly workability of an electric compressor to which an inverter circuit section and a filter circuit section are attached is improved. The inverter circuit section (3) includes an inverter control board (17), a sleeve assembly (18), and a power module (14). The inverter control board, the sleeve assembly, and the power module are integrated. The filter circuit section (4) includes a filter circuit board (66) and a support member (67). The filter circuit board (66) and the support member (67) are integrated. The inverter circuit section and the filter circuit section are structured to be capable of being stored each individually within an inverter storing section (8) from the same direction and detachably attached to the housing (2).

A camera module according to an embodiment of the present technology includes a first component-mounting board, a second component-mounting board, and a spacer component. The first component-mounting board includes an imaging device. The second component-mounting board is electrically connected to the first component-mounting board. The spacer component is arranged between the first component-mounting board and the second component-mounting board. The spacer component includes a component body that is made of a first insulating material. The component body including a first primary-surface portion that includes a plurality of first reference surfaces including at least three first reference surfaces, a second primary-surface portion that includes a plurality of second reference surfaces including at least three second reference surfaces, and a component accommodation portion with or without a bottom, the first primary-surface portion being brought into contact with the first component-mounting board, the second primary-surface portion being brought into contact with the second component-mounting board, the component accommodation portion being provided to at least one of the first primary-surface portion or the second primary-surface portion.

A method for underfilling an electronic circuit assembly may include mounting one or more structures to a substrate, mounting one or more spacers to the substrate at one or more positions, respectively, to form one or more passages between the one or more spacers and the one or more structures, dispensing underfill to the one or more passages, and curing the underfill to secure the one or more structures to the substrate. The one or more structures may include one or more dies.

An electrical junction box includes a conductive input busbar, a conductive output busbar electrically connectable to the input busbar, a semiconductor relay electrically connected to the input busbar and the output busbar and configured to switch a connected state and a disconnected state of the input busbar and the output busbar, a substrate having mounted thereon a control circuit configured to output a control signal for controlling the semiconductor relay, and a control terminal electrically connecting the control circuit and the semiconductor relay to each other to output the control signal to the semiconductor relay. The semiconductor relay is mounted on at least one of the input busbar and the output busbar. The input busbar, the output busbar, and the semiconductor relay are disposed away from the substrate.

A component having electrical connector elements for making contact with a circuit board, optionally having additional securing elements for mechanical stability after soldering or positioning devices for supporting components with an unfavourable center of gravity or supporting elements which can optionally be removed after the soldering process. The positioning devices or supporting elements serve to position components with different forms on a circuit board and to keep them in the correct orientation for the soldering process. Fitting takes place in a force-free manner and thus favours automation and the use of for example pick-and-place robots which take hold of and move the particular component via the positioning device connected thereto, engaging with and/or around either a contact element or a supporting element. The support of the positioning device allows a stable state during the soldering process. In a corresponding manner, methods for carrying out the soldering processes are specified.

The present disclosure provides a bracket for an electronic component. The bracket includes a bearing part configured to bear an electronic component and two side walls. The two side walls are oppositely arranged and disposed at the same side of the bearing part. The two side walls of the bracket are configured to be disposed on a mainboard and define together with the mainboard and the two side walls an accommodating space. The present disclosure further provides an electronic component assembly and a mobile terminal.

The present disclosure provides a bracket for an electronic component. The bracket includes a bearing part configured to bear an electronic component and two side walls. The two side walls are oppositely arranged and disposed at the same side of the bearing part. The two side walls of the bracket are configured to be disposed on a mainboard and define together with the mainboard and the two side walls an accommodating space. The present disclosure further provides an electronic component assembly and a mobile terminal.

An apparatus is provided with a component configured to be operatively coupled to an interface. In a first state, the component is mechanically and/or electrically attached to a substrate. Exposure of the interface to a thermal event that meets or exceeds a first temperature the resilient material is subject to undergo a state change to a second state. The state change includes a physical transformation of the interface, and includes a position change of the component.

Chip-on-board (COB) modular lighting systems and methods of manufacture are described herein. A system includes a COB assembly including a thermally conductive plate and a COB light-emitting diode (LED) device thermally coupled to the thermally conductive plate. The COB LED device includes multiple LED chips disposed on a surface of a substrate. The substrate includes first electrical power contacts exposed from at least the surface. The system further includes an electronics board that has second electrical power contacts. The electronics board is attached to the COB assembly such that the first and second electrical contacts are electrically coupled and the thermally conductive plate is attached to the electronics board.

Methods to form a device whereon flexible component elements are attached upon three-dimensional surfaces are described. In some aspects, the present invention includes incorporating flexible semiconductor devices onto three-dimensional surfaces with electrical contacts. In some aspects, the formed device may be incorporated in an ophthalmic device.