A reflective composite material with a carrier consisting of aluminum with, on one side (A) of the carrier, an interlayer made of aluminum oxide, and with, above the interlayer, an optically active reflection-boosting multilayer system. In order to provide a high-reflectivity composite material of this kind which exhibits improved electrical connectivity when surface-mounting procedures are used, it is proposed that the thickness of the interlayer is in the range 5 nm to 200 nm, and that a layer of a metal or a metal alloy has been applied superficially on side (B) of the carrier that is opposite to the optically active reflection-boosting multilayer system, where the electrical resistivity at 25° C. of the metal or metal alloy is at most 1.2×10.sup.−1 Ωmm.sup.2/m, where the thickness of the layer applied superficially is in the range 10 nm to 5.0 μm.

An optoelectronic device (LV) with a reflective composite material (V) having a carrier (1) consisting of aluminium, having an interlayer (2) composed of aluminium oxide present on one side (A) of the carrier (1) and having a reflection-boosting optically active multilayer system (3) that has been applied via the interlayer (2). The interlayer (2) consisting of aluminium oxide has a thickness (D.sub.2) in the range from 5 nm to 200 nm and that, on the opposite side (B) of the carrier (1) from the reflection-boosting optically active multilayer system (3), a superficial layer (9) of a metal or metal alloy having, at 25° C., a specific electrical resistivity of not more than 1.2*10.sup.−1 Ωmm.sup.2/m has been applied. The thickness (D.sub.9) of the superficially applied layer (9) is in the range from 10 nm to 5.0 μm. For an optoelectronic device (LV), the leadframe (LF) has a metallic material with an aluminium carrier (1), on the surface (A) of which a metallic joining layer (FA) not consisting of aluminium has been applied locally at the bonding site (SP) of an electronic surface-mounted device (SMD) to a wire (D).

A method is provided for producing a printed circuit board including at least one conductor element, which extends between connection points in the printed circuit board. In order to increase the productivity of a known method for producing a printed circuit board including at least one conductor element, which extends between connection points in the printed circuit board, the method comprises the following steps: Step A: providing a mold having at least one receptacle for a conductor element; Step B: arranging a conductor element in the receptacle of the mold; Step C: connecting the conductor element arranged in the receptacle of the mold to an electrically conductive sheetlike element at positions of the intended connection points; Step D: embedding the conductor element, which is connected to the electrically conductive sheetlike element, into insulating material; and Step E: working out the connection points from the electrically conductive sheetlike element.

A flexible circuit comprises a laminated substrate, a layer of a protective coating, and first and second components. The laminated substrate comprises a support layer and a conductive layer arranged on the support layer. The conductive layer includes conductive traces. Edges of the conductive traces taper outwardly and towards the support layer. The layer of the protective coating is deposited on the conductive traces. The first component is soldered at a first connection point on one of the conductive traces. The soldering sublimates the protective coating. The second component is connected to the conductive layer at a second connection point. The second connection point is free of the protective coating.

Methods and apparatus for providing an interconnection including a stack of wirebond balls having a selected impedance. The wirebond balls may have a size, which may comprise a radius, configured for the selected impedance. The stack may comprise a number of wirebond balls configured for the selected impedance and/or may comprise a material selected for the selected impedance. In embodiments, the selected impedance is primarily resistive (e.g., 50 Ohms), such that the overall reactance is minimized.

A battery connection module is provided and is adapted to connect a plurality of batteries, the battery connection module includes busbars, a circuit board and bridging pieces. The busbars are used to be connected to the batteries. The bridging pieces are connected between the corresponding busbars and the circuit board, each bridging piece has a circuit board connection segment and a busbar connection segment which are arranged along a straight direction and are respectively connected to the circuit board and the corresponding busbar and a buffering segment which is positioned between the circuit board connection segment and the busbar connection segment, the buffering segment includes at least two buffering strips, the at least two buffering strips are constructed as symmetry in a transverse direction with respect to a central line extending along the straight direction, each buffering strip has at least one curving portion.

A method for working a first component and a second component comprises the following steps: providing the first component, which comprises a thermally sprayed electrically conductive layer, providing the second component, which has a longitudinally extended strip of copper, which at least in a first region has a thickness transversely to the longitudinal direction of more than 0.1 millimeter, arranging the strip and the layer one on top of the other, so that the first region of the strip and the layer have a contact region in common with one another, emitting a laser beam onto the contact region and forming a welded connection, which connects the strip and the layer to one another.

The present invention relates to a sensing assembly and a battery module that may have a relatively low weight, simplify a component assembly process, reduce manufacturing cost, and prevent a sensing leg from being damaged due to an assembly step or an external force. The sensing assembly may include a first substrate having at least one first terminal and at least one second terminal provided on one surface and formed of a rigid printed circuit board, a second substrate including at least one sensing line electrically connected to the first terminal and formed of a flexible printed circuit board, and a sensing leg having one end electrically connected to the second terminal and including a fuse part that is disconnected when an excessive current flows.

A method of manufacturing a flexible circuit comprises providing a laminated substrate that includes a conductive layer, an adhesive layer, and a support layer. The method comprises forming conductive traces by removing selected portions of the conductive layer and the adhesive layer by dry milling the laminated substrate. The method comprises applying a protective coating to the conductive traces. The method comprises dispensing a solder material on the protective coating at a first connection point and arranging a first component at the first connection point. The method comprises heating the solder material to remove the protective coating from the first connection point and to connect the first component to one of the conductive traces at the first connection point. The method comprises attaching a second component to the conductive layer at a second connection point that is free of the protective coating by a process other than soldering.

The object is to provide a technology capable of increasing the reliability of a power semiconductor device. A power semiconductor device includes: a substrate including an insulating layer and a circuit pattern that are disposed in this order; a power semiconductor element electrically connected to the circuit pattern; and an electrode terminal having a thinned portion including a welded portion welded to the circuit pattern by a fiber laser. A thickness of the circuit pattern is not less than 0.2 and not more than 0.5 mm, and a thickness of the thinned portion of the electrode terminal is not less than one time and not more than two times the thickness of the circuit pattern.