An electronic package including a first substrate, a second substrate, a first standoff substrate, and a second standoff substrate. A clearance is formed between the first standoff substrate, the second standoff substrate, the first substrate, and the second substrate. The first standoff substrate comprises an intervening plurality of TSVs passing through an entire thickness of the first standoff substrate. The second standoff substrate comprises an intervening plurality of TSVs passing through an entire thickness of the second standoff substrate. A portion of the second plurality of TSVs are electrically connected to a portion of the first TSVs by way of a portion of the intervening TSVs. A first electronic component disposed within the clearance and electrically coupled to the first substrate by a first plurality of electrical connections. A second electronic component disposed within the clearance and electrically coupled to one of the first substrate or the second substrate. The first electronic component and the second electronic component are spaced apart from one another.

A component mounting system and apparatus are provided that include a component mounting apparatus with a substrate holding device, a component supplying device, a head support portion, a mounting head and a forcing means. The mounting head is detachably attached to the head support portion. The mounting head of the system has a recording medium in which information relating to the mounting head is recorded. The system has an external storage portion that stores a plurality of batches of information relating to a plurality of mounting heads. The system further includes a recognizing portion that obtains and recognizes information from the external storage corresponding to the mounting head that is attached to the support portion.

Integrated circuits are described which directly connect a semiconductor interposer to a motherboard or printed circuit board by way of large pitch connections. A stack of semiconductor interposers may be connected directly to one another by a variety of means and connected to a printed circuit board through only a ball grid array of solder bumps. The stack of semiconductor interposers may include one or more semiconductor interposers which are shifted laterally to enable directly electrical connections to intermediate semiconductor interposers. The top semiconductor interposer may have no electrical connections on the top to increase security by making electrical taps much more difficult. An electrically insulating layer may be incorporated between adjacent semiconductor interposers and cavities or air gaps may also be included within one or more semiconductor interposers.

Provided is an apparatus for mounting an electronic component having a plurality of board insert type leads on a board. The apparatus includes a mounting head having a first chuck unit which chucks one of the plurality of leads of the electronic component, a second chuck unit which chucks another one of the plurality of leads and a position adjusting unit which changes relative positions of the first chuck unit and the second chuck unit to hold the electronic component, and a mounting head moving unit which moves the mounting head to insert the leads of the electronic component held by the mounting head respectively into lead insert holes provided in the board.

A working apparatus includes a component holder that holds a component and mounts the component at a predetermined position of a work. In the working apparatus, the component holder that holds a component is configured to include a pair of grip members that pinch and grip the component, a grip member opening/closing portion that opens and closes the pair of grip members with an opening/closing motor as a drive source, a pair of contact portions that are disposed on the pair of grip members and freely rotate around a rotary shaft provided in an opening/closing direction of the grip member, and a contact portion driving portion that causes a roller, which is provided to be in contact with a side of a nozzle shaft, to convert a lifting and lowering motion of a nozzle shaft into a rotational motion of a spline shaft, and that causes the rotational motion to be transmitted to the contact portion via a plurality of rollers such that the contact portion rotates around the rotary shaft.

The present invention relates to connector tools for seating connectors on a substrate such as a printed circuit board. In various embodiments, the connector tools can be made by wire electrode discharge machining (WEDM) process. In the embodiments, the connector tool includes reinforced ribbed end walls, ribbed internal walls, interconnected walls and contours that reduce tool and connector damage. In other embodiments, the connector tools include guiding structures that align the connector tool to the connector before seating the connector so that the connector tool aligns to the connector pins and body to avoid damage to the connector and/or the substrate. In another embodiment, the connector tool has guiding skirts and surfaces to capture the connector in position then seat the connector. Thus, the invention reduces connector and substrate damage during manufacturing, reduces tool damage, and lowers product costs by boosting manufacturing yields.

An integrated circuit package comprising a heat spreader; one or more substrate(s); one or more standoff(s); and one or more electronic component(s). One or more component(s) is/are coupled to a substrate and the substrate maybe coupled to a heat spreader. Standoff(s) are coupled on the heat spreader or substrates forming a cavity, and one or more component(s) and substrate(s) are located inside the cavity.

A position and orientation of an electronic component attitude are recognized, a mounting head is moved above the electronic component, a rotator is horizontally rotated so that a lower surface of the electronic component is oriented in a direction opposite to a pusher, the electronic component of the fallen-down attitude is sucked and held by the nozzle by lowering a component holder, a attitude of the electronic component that is held is changed to a stand-up attitude by vertically rotating the component holder, leads of the electronic component of which the attitude is changed to the stand-up attitude and insertion holes of the substrate into which the leads are inserted are positioned, and the leads are inserted into the insertion holes of the substrate by pushing the electronic component toward the substrate by causing the pusher to abut against an upper surface of the electronic component of the stand-up attitude.

A cabinet for housing electronic plug-in cards has front and rear card baskets for inserting plug-in cards and first and second vertical backplanes. The front side of the first backplane faces the front of the cabinet and the front side of the second backplane faces the back of the cabinet. A distance piece connects the two backplanes and a counterbore is disposed in at least one of the rear sides of the two backplanes. The depth of the counterbore or the residual thicknesses of the backplane after drilling the counterbore is sized such that the distance between the front side of the second backplane and the front of the cabinet is a predetermined value. This ensures that the plug-in cards pushed onto the second backplane are completely received inside the rear card basket and the front plate of the plug-in cards ends flush with the rear card basket.

Methods and systems for stacking multiple chips with high speed serializer/deserializer blocks are presented. These methods make use of Through Via (TV) to connect the dice to each other, and to the external pads. The methods enable efficient multilayer stacking that simplifies design and manufacturing, and at the same time, ensure high speed operation of serializer/deserializer blocks, using the TVs.