A method for attaching two electronics boards, e.g., a testing PCB and a space transformer, comprises rack welding resin prepreg and a mylar film to a testing PCB; laser drilling via holes in the resin prepreg and mylar film such that the holes are aligned on one side of the resin prepreg with connection/capture pads on the testing PCB and aligned (after attachment) on the other side of the resin prepreg with connection capture pads on a space transformer, filling the via holes with sintering paste; applying a pressure treatment to remove air, bubbles, and voids from the sintering paste; removing the mylar film; and using a lamination press cycle to attach a space transformer to the resin prepreg.

There is provided a method which includes placing a component on a substrate and extending an alignment member through an opening in the substrate. Once the alignment member is extended through the opening, the component is moved to abut against the alignment member to align the component relative to the substrate. After the component is aligned relative to the substrate, the component is secured to the substrate and the alignment member is retracted through the opening.

A printed circuit board, in which two or more copper clad laminates (CCLs) are laminated vertically from an uppermost circuit layer to a lowermost circuit layer, includes a non-destructive testing area, mislamination identifying portions in the non-destructive testing area, the mislamination identifying portions being in the CCLs, respectively, through-via holes vertically exposing the mislamination identifying portions, respectively, in the non-destructive testing area, the through-via holes being spaced apart from each other by a first interval, and a probe via extending vertically and being in contact with an end portion of each of the mislamination identifying portions on a same side. A length of the mislamination identifying portion in an N-th (N is an integer of 1 to K) layer CCL in a horizontal direction is longer than a length of the mislamination identifying positioned in an (N-1)-th layer CCL in the horizontal direction.

A PCB includes a plurality of layers spaced apart in a vertical direction, a first detection pattern and a second detection pattern and pads connected to the first detection pattern and the second detection pattern. The first detection pattern and the second detection pattern are provided in a respective one of a first layer and a second layer adjacent to each other such that the first detection pattern and the second detection pattern are opposed to each other. The pads are provided in an outmost layer. Each of the first detection pattern and the second detection includes at least one main segment extending in at least one of first and second horizontal directions and a diagonal direction. A time domain reflectometry connected to a pair of pads detects a misalignment of the PCB by measuring differential characteristic impedance of the first detection pattern and the second detection pattern.

An apparatus to automatically place layers of a printed circuit board on a fixture includes a robotic device having a base that is secured to a surface, an upright column that extends upwardly from the base, and a movable arm rotatably coupled to the upright column. The movable arm is configured to rotate about a vertical axis defined by the upright column. The movable arm is further configured to rotate from a position in which the movable arm is disposed over a laminate sheet fixture and to pick up a laminate sheet to a position in which the movable arm is disposed over a board layup fixture to deposit the laminate sheet in the board layup fixture, and from a position in which the movable arm is disposed over a bond film fixture and to pick up a bond film to a position in which the movable arm is disposed over the board layup fixture to deposit the bond film in the board layup fixture.

A tool for supporting multilayer printed circuit boards during manufacture having a frame in which there is fixed a pretensed, non-electrically conductive fabric which has a thickness less than 0.1 mm and which can be accessed by its two faces. The tool allows the induction bonding of the layers at internal points of the bundle following a method in which the bundle is placed on the tool and at least one of the welding electrodes used in the welding operation is applied on the lower face of a fabric of the tool supporting the bundle. A machine especially suitable for putting the method into practice includes C-shaped magnetic cores, the arms of which are long enough to reach the internal points of the bundle.

A method for producing a ceramic multilayer element is disclosed. In an embodiment the method includes forming a plurality of multilayer segments in a green state, wherein each multilayer segment is formed by pressing together a plurality of ceramic layers in the green state and pressing together the multilayer segments in the green state to form a multilayer element that is in the green state. The method further includes sintering the multilayer element that is in the green state to form a ceramic multilayer element that includes the ceramic layers and electrode layers arranged one on top of another, wherein at least one or more of a temperature at which the multilayer segments are pressed together, a pressing force applied during the pressing of the multilayer segments, and/or a duration of the pressing of the multilayer segments are adjusted.

An electronic element mounting substrate includes a first insulating layer, a second insulating layer, a first metal layer, and a through-hole conductor. The first insulating layer and the second insulating layer are aligned in a first direction. The first metal layer is positioned between the first insulating layer and the second insulating layer. The through-hole conductor extends in the first direction from the first insulating layer through the second insulating layer. The first metal layer includes a first portion positioned away from the through-hole conductor and a second portion in contact with the through-hole conductor. The second portion has a larger thickness than the first portion.

A method for manufacturing a multilayer wiring board is disclosed. The method includes steps of preparing printed wiring boards having both electrical connection pads for establishing an electrical connection between the boards and non-connection pads for not establishing an electrical connection between the boards on the same plane, overlaying the boards so that the electrical connection pads face each other, and laminating the boards so that the boards are bonded to each other through a conductive paste provided between the facing electrical connection pads. To prepare the printed wiring boards, attach an insulating film to at least one of surfaces faced when the boards are overlaid in the overlaying, bore holes in the insulating film so that the electrical connection pads are exposed, and provide a conductive paste in the holes.

A manufacturing method of multilayer printed circuit boards has steps as follows: aligning circuit layers with a stacking location to form a substrate having multiple positioning portions; pre joining the substrate at the positioning portions; forming an alignment hole in each positioning portion; and placing the pre joined substrate over alignment pins of a press device for lamination. After the circuit layers are aligned, the substrate is pre joined at the positioning portions, and then the alignment holes are formed in the positioning portions for pins alignment at the press device. The alignment accuracy is enhanced. Dusts will not deposit onto surfaces of the circuit layers to damage circuits thereof.