A surface mounted technology (SMT) process prediction tool for intelligent decision making on PCB quality is disclosed. A data fusion tool automatically reads size parameters and component information on design conditions of a printed board to be assembled from a database and creates a design condition list for different components for a software execution layer; a printing parameter decision-making toolkit and a soldering parameter decision-making toolkit in the software execution layer perform comparisons on printing and soldering data according to design conditions of components on the printed board to be assembled, perform automatic decision making on printing and soldering parameters with a multi-objective optimization algorithm and a deep learning algorithm, predict printing quality and soldering quality, and send decided printing and soldering process parameters and corresponding predicted quality results to a human-computer interaction toolkit, to visually display the printing and soldering process parameters and the predicted quality values.

An electronic component includes a housing and a cover. The housing includes a concave portion accommodating therein elements. The cover covers the concave portion. A laser-welded portion including a discontinuous portion is provided along a circumference of the concave portion of the housing and fixes the cover to the housing.

A housing includes a concave portion in which components are to be accommodated. A cover covers the concave portion. A first laser-welded portion is provided along a circumference of the concave portion of the housing and fixes the cover to the housing. The cover includes an opening positioned inside of the first laser-welded portion and corresponding to a part of the circumference of the concave portion of the housing.

A solder composition of the invention contains: a flux composition containing (A) a rosin resin, (B) an activator, (C) an imidazoline compound having a phenyl group, and (D) an antioxidant; and (E) solder powder, in which the (B) component contains (B1) an organic acid, the (B1) component contains at least one selected from the group consisting of (B11) 1-hydroxy-2-naphthoic acid, 3-hydroxy-2-naphthoic acid, and 1,4-dihydroxy-2-naphthoic acid, and the (C) component is at least one selected from the group consisting of 2-phenylimidazoline and 2-benzylimidazoline.

Embodiments for a circuit board comprising a plurality of electrically conductive layers and a plurality of electrically non-conductive layers in a laminated stack are provided. The laminated stack defines a front face and a back face. A thermal conductive heat body extends from a die bond pad on the front face to an electrically conductive layer on the back face. The die bond pad is configured for a bare die to be mounted thereon. A bonding agent disposed around the thermal conductive heat body adhering the thermal conductive heat body to walls of an opening of the laminated stack and at least one of the plurality of electrically non-conductive layers are a monolithic structure. A plurality of wire bond pads on the front face adjacent to the die bond pad have a surface finish material thereon. The surface finish material is configured for wire bonding thereto.

In component mounting for mounting a pin connecting component having a pin on a board having a through-hole electrode, a solder paste is printed on the through-hole electrode through a screen mask having an opening corresponding to the through-hole electrode, a flux is transferred onto the pin by holding the pin connecting component and immersing the pin into a flux tank filled with the flux, and the pin onto which the flux is transferred is inserted into the through-hole electrode on which the solder paste is printed to mount the pin connecting component on the board.

Methods for attachment and devices produced using such methods are disclosed. In certain examples, the method comprises disposing a capped nanomaterial on a substrate, disposing a die on the disposed capped nanomaterial, drying the disposed capped nanomaterial and the disposed die, and sintering the dried disposed die and the dried capped nanomaterial at a temperature of 300° C. or less to attach the die to the substrate. Devices produced using the methods are also described.

A component mounting device includes a mounting portion that mounts a component on a bonding material disposed on a substrate, and a measurement unit that measures a state of the bonding material at least after an operation of mounting the component performed by the mounting portion. The component mounting device further includes a control unit that verifies the state of the bonding material based on a measurement result obtained by the measurement unit when defective mounting of the component has occurred.

According to one embodiment, an electronic device includes a flexible printed wiring board includes an insulating layer, a plurality of connection pads provided on one side of the insulating layer and constituting a group, and a pad provided on another surface side of the insulating layer and having heat conductivity, wherein the pad overlaps one or more connection pads positioned at an outer edge of the group of connection pads via the insulating layer and comprises a portion extending on the outside of the connection pad on the outer edge, and a connection member includes a plurality of connection terminals connected to the connection pads via a solder.

A pressing device includes a screw body. The screw body includes a screw head that comprises a driver interface. The screw body also includes a screw shaft that comprises a screw tip opposite the screw head with respect to the screw shaft, exterior spiral threads between the screw head and screw tip, and an interior cavity with an opening at the screw tip. The pressing device also includes a pin partially inserted into the interior cavity. The pin comprises a first pin end inserted into the interior cavity, a pin shaft that is connected to the first pin end, and a second pin end that is connected to the pin shaft and that is exterior to the interior cavity. Applying a force to the second pin end in a direction towards the screw head causes the pin shaft to advance into to interior cavity.