The invention relates to a method for producing a printed circuit boardcooling body structure and such a printed circuit boardcooling body structure, in particular for arrangement in a lighting device of a vehicle, the method comprising at least the following steps: providing a base plate; coating a carrier side of the base plate with an insulation layer and/or with a solder resist; fitting the carrier side with at least one electronic component and applying cooling rib bodies to a cooling side of the base plate opposite the carrier side.

A mounting assembly includes an electronic component mounted on an upper surface of a circuit board and having at least one electrical connector and a thermal pad provided on a lower surface of the component. The circuit board is mounted on a heatsink and provided with an opening beneath the thermal pad of the component. The heatsink has a heatsink extension which extends through the circuit board and is spatially separated therefrom. A thermal interface material is provided to ensure an electrically insulating thermal connection between the thermal pad and the heatsink extension.

A printed wiring board for camera module includes: first and second mounting regions for first and second image pickup devices respectively provided on one and the other sides in a front surface of the printed wiring board, the first and second mounting regions respectively provided with first and second conductive patterns configured to be electrically connected to the first and second image pickup devices, respectively, and a component mounting region provided between the first mounting region and the second mounting region, the component mounting region provided with a third conductive pattern, the third conductive pattern configured to be electrically connected to a signal processing component, amounting density of the third conductive pattern in the component mounting region being higher than that of the first conductive pattern in the first mounting region or a mounting density of the second conductive pattern in the second mounting region, in a plan view.

The present invention relates to a metallic nano structure including a plurality of metallic nano materials; and a junction locally disposed in a region where the metallic nano materials adjacent to each other among the plurality of metallic nano materials are in contact with each other in order to bond the adjacent metallic nano materials.

Examples of a thermal management unit and an electronic apparatus utilizing the thermal management unit are described. In one aspect, the thermal management unit includes a heat sink. The heat sink includes a base portion, a first protrusion structure and a second protrusion structure. The base portion has a first side and a second side opposite the first side. The first protrusion structure protrudes from the first side of the base portion, and includes multiple fins. The second protrusion structure protrudes from the second side of the base portion, and includes multiple ribs. The heat sink may be made of silicon.

A method for mounting a printed circuit board for an automotive vehicle on a carrier structure including at least one rivet. The printed circuit board includes at least one mounting aperture that is capable of accommodating the rivet and which defines an electrical conduction zone and at least one mark having a control end up to which the mark extends over the electrical conduction zone. The method includes a step of positioning the printed circuit board on the carrier structure such that the rivet extends through the mounting aperture, a step of riveting the rivet such that its head is at least partly flattened on the electrical conduction zone and a step of determining the conformity of riveting when the head of the rivet covers the control end of the mark.

A surface-treated copper foil according to exemplary embodiments includes a copper foil layer and a protrusion layer formed on one surface of the copper foil layer. Pores are formed inside the protrusion layer or around a boundary between the copper foil layer and the protrusion layer. Abnormal growth of the protrusions may be prevented through the pores and thus a bonding force with the insulation layer may be improved.

Provided is a mounting structure that can bond a first heat dissipation element to a second substrate through a hole in a first substrate without using a binder such as solder, an adhesive, or the like. A mounting structure of the present disclosure includes a first substrate (10) in which a penetrating hole (11) is formed, a second substrate (20) and a first heat dissipation element (30) overlapped with both surfaces of the first substrate (10), respectively, so as to cover the penetrating hole (11), and a second heat dissipation element (40) sandwiched and attached between the second substrate (20) and the first heat dissipation element (30) inside the penetrating hole (11).

A metal-ceramic bonded substrate is such that a heat dissipating face is formed in a spherical protruding form, because of which contact pressure with a thermally conductive grease when attaching a heat dissipating fin to the heat dissipating face is high, and high heat dissipation can be secured. Also, by an overflow portion communicating with a metal base portion formation portion being provided farther to an outer side than an external form of the metal-ceramic bonded substrate in an interior of a casting mold, an overflow portion residue is restricted by the casting mold when causing molten metal to solidify and cool, because of which warping deformation occurring because of a difference between linear expansion coefficients of a metal material and a ceramic material can be restricted, and a casting defect such as a running defect in a molten metal flowing process, cold shut, a ripple mark, can be restricted.

A method for mounting a printed circuit board for an automotive vehicle on a carrier structure including at least one rivet. The printed circuit board includes at least one mounting aperture that is capable of accommodating the rivet and which defines an electrical conduction zone and at least one mark having a control end up to which the mark extends over the electrical conduction zone. The method includes a step of positioning the printed circuit board on the carrier structure such that the rivet extends through the mounting aperture, a step of riveting the rivet such that its head is at least partly flattened on the electrical conduction zone and a step of determining the conformity of riveting when the head of the rivet covers the control end of the mark.