A method for forming a silicon carbide module integrated structure includes a heat sink and a silicon carbide module, which is fixedly connected with the heat sink. The solder paste is arranged between the heat sink and the silicon carbide module, and the heat sink and the silicon carbide module are hot pressed through a welding process to weld the silicon carbide module and the heat sink together.

A method of manufacturing a printed circuit board assembly includes providing a circuit board, positioning a plurality of components including at least one thermally-sensitive component having a maximum temperature threshold on the circuit board, positioning a customized protective heat shield on the thermally-sensitive component, exposing the circuit board (having the thermally-sensitive component disposed thereon and the customized protective heat shield disposed on the thermally-sensitive component) to a high-temperature environment wherein temperatures exceed the maximum temperature threshold of the thermally-sensitive component, and removing the customized protective heat shield from the thermally-sensitive component. Customized protective heat shields are also provided.

An apparatus for determining the condition of a printed circuit board, including a stencil database for storing a plurality of stencil data files corresponding to stencils of different dimensions, an image capturing device having an area where the printed circuit board is laid thereon for a surface profile of the printed circuit board to be captured for generating a surface data file of the printed circuit board, and a condition determination module that compares data from the surface data file with data from one or more stencil data file as a nominal reference via a matching process to determine the condition of the printed circuit board based on a set of categories. The printed circuit board is sent for further processing (i.e., stencil printing) after being determined to be in a match-successful condition where data from the surface data file falls within a tolerance of the nominal reference.

An apparatus for producing a printed circuit board on a substrate, has a table for supporting the substrate, a function head configured to effect printing conductive and non-conductive materials on the substrate, a positioner configured to effect movement of the function head relative to the table, and a controller configured to operate the function head and the positioner to effect the printing of conductive and non-conductive materials on the substrate. The apparatus optionally has a layout translation module configured to convert PCB files or multilayer PCB files to printing data for controlling the function head to print conductive material and nonconductive material onto the substrate. The apparatus has a testing head to verify conductors which operates automatically. The translation module also prints nonconductive material component alignment areas and nonconductive material substrate stiffeners.

Precisely aligned assemblies can be complex, time consuming, labor intensive, and expensive and a need exists for better alternatives. Systems and methods described herein yield high precision printed circuit board assemblies (PCBAs) that contain pre-built alignment features to address this need. The work of precisely locating components on the PCBA to a final position in the overall assembly is already built in to the board. Locating features are used to precisely position one or more components, such as optical components, electro optical components, or mechanical components in assemblies. The locating features may be used to constrain the positions of those components, such as by kinematic coupling, solder wetting dynamics, semiconductor cleaving, dicing, photolithographic techniques for etching, constant contact force, and advanced adhesive technology to result in optical level positioning that significantly improves or eliminates assembly alignment challenges.

A multilayer ceramic electronic component includes multilayer ceramic electronic component bodies each including a laminate and first and second outer electrodes respectively disposed on two end surfaces of the laminate, first and second metal terminals respectively connected to the first and second outer electrodes, and first and second terminal blocks respectively connected to the first and second metal terminals. A thickness dimension of each multilayer ceramic electronic component body in a height direction is less than a width dimension of the multilayer ceramic electronic component body in a width direction. Each multilayer ceramic electronic component body is disposed such that a first or second side surface faces a mounting surface. The first and second metal terminals are respectively disposed astride the first and second outer electrodes of the multilayer ceramic electronic component bodies.

A circuit board includes a substrate, a first inner circuit layer, a second inner circuit layer, a first insulating layer, a first optical fiber extending along a first direction, an optical component, an electrical component, a transparent insulating layer, a first inclined surface, a first reflective layer, a second inclined surface, a second reflective layer, and a second optical fiber extending along a second direction.

The present disclosure provides an inspection device for use in a mounting system including a mounting device for disposing a component on a board, including a control section configured to extract a mass area included in a captured image resulting from imaging a processing target object where a viscous fluid is formed at a predetermined part, obtain a center of gravity of the mass area so extracted, and determine whether the center of gravity is included in a normal range of the predetermined part as a reference of the captured image to thereby determine whether a bridge has occurred where the viscous fluid is formed over adjacent predetermined parts.

A method of manufacturing a printed circuit board assembly includes providing a circuit board, positioning a plurality of components including at least one thermally-sensitive component having a maximum temperature threshold on the circuit board, positioning a customized protective heat shield on the thermally-sensitive component, exposing the circuit board (having the thermally-sensitive component disposed thereon and the customized protective heat shield disposed on the thermally-sensitive component) to a high-temperature environment wherein temperatures exceed the maximum temperature threshold of the thermally-sensitive component, and removing the customized protective heat shield from the thermally-sensitive component. Customized protective heat shields are also provided.

A soldering component and a method of fitting it to boards are introduced. The soldering component includes a body and a fitting portion. The fitting portion is fitted to an object. The body has an engaging portion with an elastic retraction space conducive to elastic retraction of two or more engagement portions, allowing the engagement portions to engage with another object. The soldering component has a weldable surface to be soldered to a weldable surface of the object. The weldable surface of the object has a built-in solder layer adapted to be heated for soldering the soldering component and the weldable surface of the object together. The soldering component is disposed in a carrier, taken out with a tool, compared with the object by a comparison device to determine a fitting position on the object, positioned at the fitting position with the tool, thereby being fitted to the object.