An IC unit unloading system including a chute and a drawer. The chute has a plurality of channels each arranged to receive a unit. The drawer is arranged to move along the chute and has a gate with a unit contact face proximate a top surface of the chute. The contact face is arranged to draw the units along the respective channel as the drawer moves along the chute, and to allow the units to slide laterally across the contact face from a first pitch of each channel to a second pitch. A method for washing a plurality of PCB units, the method comprising the steps of: receiving a plurality of PCB units, said PCB units arranged with a bump face projecting downwards; washing the bump face of the PCB units, then; flipping the PCB units so as to project the ball face downwards, then; washing the ball face.

A method for connecting stacked circuit boards includes: a connecting structure is provided, the connecting structure is a bendable and flexible circuit board; a first circuit board and a plurality of supporting posts are provided, each of the supporting posts is dispersedly fixed to a side surface of the first circuit board; a second circuit board is provided, and two peripheral portions of the connecting structure are respectively fixed to the first circuit board and the second circuit board, the peripheral portions of the connecting structure are respectively near two opposite ends of the connecting structure; the connecting structure is bent to flip the second circuit board super-positioned above the first circuit board, and the second circuit board is connected to a free end of each of the supporting posts.

A method of producing electronic components each including a substrate-type terminal and a device connected to the substrate-type terminal including a substrate body with first and second principal surfaces opposite to each other and an electrode configured to be connected to the device on the first principal surface, wherein the device is disposed on the first principal surface, includes forming grooves in a substrate from one of the first and second principal surfaces of the substrate such that the substrate is divided into the substrate-type terminals, the grooves each having a depth less than a thickness of the substrate, cutting the substrate from another principal surface opposite to the principal surface of the substrate body such that the grooves penetrate through the substrate in a thickness direction thereof, and mounting the device on each of the first principal surfaces.

A wiring board includes electronic components, a multilayer core substrate including insulating layers and conductive layers such that the insulating layers include a central insulating layer in the center position of the core in the thickness direction, a first build-up layer including an insulating layer and a conductive layer such that the insulating layer has resin composition different from that of the insulating layers in the core, and a second build-up layer including an insulating layer and a conductive layer such that the insulating layer has resin composition different from that of the insulating layers in the core. The core has cavities accommodating the electronic components, respectively, and including a first cavity and a second cavity such that the first and second cavities have different lengths in the thickness direction and are penetrating through the central layer at centers of the first and second cavities in the thickness direction.

A method of producing electronic components each including a substrate-type terminal and a device connected to the substrate-type terminal is performed such that the substrate-type terminal includes a substrate body including a rectangular or substantially rectangular first principal surface extending in first and second directions perpendicular or substantially perpendicular to each other. The device is disposed on the first principal surface. The method includes supporting a substrate that is to become an assembly in which the plurality of substrate-type terminals are arranged in a matrix using a first support member, cutting the substrate supported by the first support member into the plurality of substrate-type terminals, and mounting the device on the first principal surface of the substrate body of each of the plurality of substrate-type terminals obtained by cutting.

The invention eliminates defects generated in a metal filling a through hole of a printed board by changing an angle at which a plating solution is sprayed or by changing a posture of the printed board at a time point in a process of precipitating the metal from the plating solution and filling the through hole with the precipitated metal while the plating solution or air bubbles are being sprayed onto the printed board.

A printing process for printing an ink pattern on a substrate is provided. The ink pattern to be printed is based on an available pattern layout. The pattern layout defines a desired layout of the ink pattern to be printed. Based on the pattern layout an input image for allocating dot positions of the ink pattern is generated. The printing process includes a step of comparing a scan image with the input image to carry out a quality inspection to detect any print defects in the printed ink pattern. The printing process includes a step of providing a decision on an approval or a rejection of the printed ink pattern. In case of an approval, the substrate can be supplied to a subsequent processing station to finalize the substrate. In case of a rejection, the substrate including print defects can be recycled.

A method for milling flex foil includes providing a web (14) of flex foil including a substrate; a first conductive layer arranged on one surface of the substrate; a second conductive layer arranged on an opposite surface of the substrate; a first insulating layer arranged adjacent to the first conductive layer; and a second insulating layer arranged adjacent to the second conductive layer. The method includes dry milling one side of the web using a milling wheel (20-1) and a first cliche pattern (25-1) (including a rotating drum (24-1) and a flexible substrate (26-1)) including raised portions and non-raised portions to selectively remove at least one of the first conductive layer and the first insulating layer. The method includes dry milling an opposite side of the web using a milling wheel (20-2) and a second cliche pattern (25-2) including upper raised portions, lower raised portions and non-raised portions to selectively remove the second insulating layer.

A deposition apparatus includes a first substrate support for supporting a substrate in a substantially vertical orientation. The substrate has a first main surface, a second main surface opposite the first main surface and a side surface between the first main surface and the second main surface. The deposition apparatus includes a first deposition device for depositing a first conductive pattern or a first resist mask on the side surface of the substrate while the substrate is supported in the substantially vertical orientation by the first substrate support.

The invention relates to an electronic module (40) comprising at least one printed circuit board of a first type (referred to as “printed circuit board A”), which is equipped in an overlapping manner with at least one printed circuit board of a second type (referred to as “printed circuit hoard B”), printed circuit board B being equipped with at least one electronic component with specific requirements (19), and the interconnected printed circuit boards A and B forming a stepped composite printed circuit board (100, 200, 300, 400, 500). The composite printed circuit board (100, 200, 300, 400, 500) is delimited at least in some regions by end regions (16) which are formed by sections of the at least one printed circuit board A, and the composite printed circuit board (100, 200, 300, 400, 500) is placed on a heat sink (20). A fastening side (15) of the at least one printed circuit board B rests flat on a contact face (21) of the heat sink (20), the contact face (21) of the heat sink (20) being dimensioned and positioned such that at least part of it extends laterally beyond the fastening side (15) of the at least one printed circuit board B in each case towards the end regions (16) formed. Supporting elements (23, 24, 25, 26) are formed on the contact face (21) of the heat sink for the mechanical support of the end regions (16). The invention also relates to a method for producing such an electronic module.