A composite flexible printed wiring board includes a first flexible printed wiring board having an insulating layer, conductor layers and a first metal block fitted in a hole penetrating through the conductor layers and insulating layer, and a second flexible printed wiring board having an insulating layer, conductor layers and a second metal block fitted in a hole penetrating through the conductor layers and insulating layer. The first flexible printed wiring board and the second flexible printed wiring board have a welded portion formed by welding the first metal block and the second metal block and joining the first metal block and the second metal block such that the welded portion is joining the first flexible printed wiring board and the second flexible printed wiring board.

A flexible printed wiring board includes a flexible insulating layer, a conductor layer formed on a surface of the flexible insulating layer, and a metal body having a columnar shape and fitted in a hole penetrating through the flexible insulating layer and the conductor layer such that the metal body is formed of a welding base material and has an end portion formed to be joined to an electrode of a battery by welding. The welding base material of the metal body of the flexible printed wiring board includes the same material as the electrode of the battery.

A printed circuit board (PCB) assembly may include a motherboard PCB with one or more plated holes and a daughterboard PCB with one or more plated fingers extending from a lower edge of the daughterboard PCB. The plated fingers may have a rectangular and/or square cross section. The plated fingers may be plated on four sides that define the rectangular cross section. Each of the plated holes may be configured to receive a respective plated finger, for example, such that a lower portion of the plated fingers extend beyond a lower surface of the motherboard PCB. Each of the plated holes may be configured to be electrically connected to a respective plated finger via a solder joint. The solder joint may extend around the respective plated finger. The solder joints for the plated fingers may be configured to secure the daughterboard PCB to the motherboard PCB.

Devices and methods related to metallization of ceramic substrates for shielding applications. In some embodiments, a ceramic assembly includes a plurality of layers, the assembly including a boundary between a first region and a second region, the assembly further including a selected layer having a plurality of conductive features along the boundary, each conductive feature extending into the first region and the second region such that when the first region and the second region are separated to form their respective side walls, each side wall includes exposed portions of the conductive features capable of forming electrical connection with a conductive shielding layer.

A method for manufacturing a sensor module having a passive electrical component comprises punching a plurality of holes in a first green sheet of a plurality of green sheets, and forming a plurality of channels and a plurality of passageways in a second green sheet of the plurality of green sheets by using a laser on the second green sheet. A metallization paste is printed in the plurality of holes, the plurality of channels, and the plurality of passageways, and the first green sheet and the second green sheet are dried with the metallization paste. The method further comprises aligning, stacking, laminating, and sintering the plurality of green sheets together to create a sintered tile, and separating a plurality of coils of the sintered tile in order to obtain the sensor module.

A method of making a printed circuit board structure including a closed cavity is provided. The method can include the steps of forming a cavity in a core structure of a core layer, laminating each of a top surface and a bottom surface of the core structure with an adhesive layer and a metal layer to prepare a laminate structure and cover the cavity to define a closed cavity. The method also includes forming vias through the laminate structure, and patterning the metal layers in the laminate structure.

Embodiments disclosed herein include a motherboard. In an embodiment, the motherboard comprises a first layer with a first trace with a shape. In an embodiment, an insulating layer is provided over the first layer. In an embodiment, a second layer with a second trace with the shape is over the insulating layer. In an embodiment, the second trace is provided directly over the first trace.

A multilayer ceramic substrate includes: a plurality of ceramic layers 300a, 300b stacked together; a via hole 400a, 400b provided in each of the plurality of ceramic layers, the via holes of the plurality of ceramic layers being connected together in a layer stacking direction of the plurality of ceramic layers; a via wire 406a, 406b including an electrical conductor filled into each of the via holes; a first conductor 404a, 404b provided on an upper surface of at least one of the plurality of ceramic layers, the first conductor having an annular or partially annular shape surrounding the via wire; and a second conductor 403a, 403b including a first portion and a second portion, the first portion being located outside the first conductor on the upper surface of the at least one ceramic layer, the second portion overlying the first conductor, and an inner rim of the second portion being located outside an inner rim of the first conductor, wherein a thickness of the first conductor 404a, 404b is greater than a thickness of the second conductor 403a, 403b.

A flexible printed circuit board according to an aspect of the present invention includes a base film having insulating properties and a conductive pattern laminated to one surface side of the base film. The conductive pattern forms part of a circuit and includes at least one fuse portion having a cross section smaller than the other part. The flexible printed circuit board includes at least one opening passing through front and rear surfaces on at least one of the right and left sides of the fuse portion in a two-dimensional view.

The present application discloses a method for fabricating ceramic insulator for electronic packaging, and relates to a technical field of outer shell packaging of electronic devices. Under the circumstance of using neither a chemical coating nor any bonding wire connection circuit, through a design that builds a electroplated circuit into the ceramic insulator, the method accomplishes coating of a nickel alloy protection layer onto a porcelain by an electroplating method, so that not only quality of a coating layer but also requirement of a complete appearance can be ensured. All circuits of the ceramic insulator fabricated by the aforesaid method can conduct with external circuits, such that the electroplating method can be used to accomplish coating of the nickel alloy layer, after accomplishment of all metal coating, metallization parts on an end surface of the porcelain is removed.