A multi-phase busbar can include a first conducting layer, a first conducting pin, a first insulating layer, and a second conducting layer. The first conducting layer can include a sheet metal coated with an electrically insulating material. The first conducting pin can be mounted to the first conducting layer. The first conducting pin can extend in a direction perpendicular to the first conducting layer. The first insulating layer of a rigid insulating material can be arranged on the first conducting layer. The first insulating layer can define an opening through which the first conducting pin projects. The second conducting layer can include a sheet metal coated with an electrically insulating material, the second conducting layer comprising a first pinhole through which the first conducting pin projects and a second conducting pin which extends in a direction parallel to the first conducting pin.

A multi-phase busbar for conducting electric energy includes: an insulating base layer made of an insulating material; a first conducting layer made of a sheet metal arranged on and adhesively bonded to the base layer; a first connecting pin mounted to the first conducting layer which extends in a direction with respect to the first conducting layer; a first insulating layer arranged on and adhesively bonded to the first conducting layer; a second conducting layer made of a sheet metal arranged on and adhesively bonded to the first insulating layer, the second conducting layer including a second connecting pin which extends in a direction parallel to the first connecting pin; and a second insulating layer arranged on and adhesively bonded to the second conducting layer. The second conducting layer and the first and second insulating layer each include at least one pinhole through which the first connecting pin projects.

A multi-phase busbar for conducting electric energy includes: a base layer of an insulating material; a first conducting layer of a sheet metal; a first insulating layer of an insulating material arranged on the first conducting layer; a second conducting layer of a sheet metal arranged on the insulating layer; and a second layer of an electrically insulating material which is arranged on the second conducting layer. The first and/or second insulating layers include spacers, each spacer including a layer of a rigid insulating material. At least one of the spacers is glued to an electrically insulating coating of the first and/or second conducting layer, and/or at least one of the spacers is glued to an electrically conductive surface of an uncoated first and/or second conducting layer by an adhesive.

A method for manufacturing a circuit board including: providing at least one wiring base board, the wiring base board comprising a first conductor layer, an insulation layer, and an alloy layer which are stacked in order, wherein a solder paste layer is formed on a side of the alloy layer, a part of the alloy layer is exposed out of the solder paste layer to form a thermal conductive surface; providing a core layer; and pressing two wiring base boards on two opposite sides of the core layer to form a sealed heat dissipating chamber between the thermal conductive surfaces of the two wiring base boards. The present disclosure further provides a circuit board having a heat dissipation structure.

A multi-layered board includes: a middle conductive layer; a first dielectric layer that is disposed directly on a first surface of the middle conductive layer; a second dielectric layer that is disposed directly on a second surface of the middle conductive layer; a first outer surface conductive layer that is disposed directly on an outer side of the first dielectric layer; and a second outer surface conductive layer that is disposed directly on an outer side of the second dielectric layer. The first outer surface conductive layer serves as a first outer surface of the multi-layered board, and the second outer surface conductive layer serves as a second outer surface of the multi-layered board. The middle conductive layer is solidly formed over an entire planar direction of the multi-layered board. The first dielectric layer and the second dielectric layer each independently have a thickness variation of 15% or less.

A ceramic substrate manufacturing method is provided in which a copper sheet is etched and then bonded to a ceramic substrate, so that the ceramic substrate has reduced to overall processing time and improved reliability and product lifespan. The ceramic substrate manufacturing method includes the steps of: etching a copper sheet so as to prepare a metal substrate; etching a ceramic substrate so as to prepare a unit ceramic substrate; assembling the metal substrate and the unit ceramic substrate; bonding the metal substrate and the unit ceramic substrate so as to form a stack; partially printing a metal paste on the surface of the stack; and sintering the metal paste.

In one embodiment of the present invention, a multilayer wiring substrate includes: a first wiring substrate having a first core member made of metal with cavities therein; a second wiring substrate having a second core member made of metal; and a bonding layer between the first wiring substrate and the second wiring substrate to bond a top surface of the first wiring substrate to a bottom surface of the second wiring substrate, the bonding layer having a patterned conductive layer.

A multilayer printed circuit board includes a first circuit board, a second circuit board and bonding films. The first circuit board includes a first dielectric layer, a first wiring pattern layer, a plurality of conductive blocks and a plurality of solder balls. The first wiring pattern layer is formed on a first surface of the first dielectric layer and the conductive blocks are formed on a second surface of the first dielectric layer. The solder balls are formed on a surface of the first wiring pattern layer. The second circuit board includes a second dielectric layer, a second wiring pattern layer, second conductive blocks and conductive pillars. The second wiring pattern layer is formed on a third surface of the second dielectric layer and the second conductive blocks are formed on a fourth surface thereof. The conductive pillars are formed on the second wiring pattern layer.

A circuit board structure with chips embedded therein includes a multi-layer board and a power module embedded in the multi-layer board. The power module includes an insulating material, a power unit covered by the insulating material, and a circuit layer disposed on the insulating material. The power unit includes an electrically and thermally conductive carrier and a plurality of power chips. The electrically and thermally conductive carrier includes a transmitting portion and a carrying portion perpendicularly connected to the transmitting portion. Each power chip has a first electrode layer and an opposite second electrode layer. The first electrode layers are fixed on and electrically connected to the carrying portion in parallel, and the power chips are disposed at one side of the transmitting portion. The circuit layer is electrically connected to the electrically and thermally conductive carrier and the second electrode layers.

A circuitized substrate which includes a conductive paste for providing electrical connections. The paste, in one embodiment, includes a metallic component including nano-particles and may include additional elements such as solder or other metal micro-particles, as well as a conducting polymer and organic. The particles of the paste composition sinter and, depending on what additional elements are added, melt as a result of lamination to thereby form effective contiguous circuit paths through the paste. A method of making such a substrate is also provided, as is an electrical assembly utilizing the substrate and including an electronic component such as a semiconductor chip coupled thereto.