A laminated busbar assembly includes positive and negative leads supported by an insulative layer. The insulative layer as well as the positive and negative leads are thin and flexible, thus facilitating connection of the positive and negative leads with the terminals of the electric cells of a battery module. The laminated busbar assembly may include voltage measurement wires and/or temperature sensors for measuring voltage and/or temperature, respectively.

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 1.210.sup.1 mm.sup.2/m, where the thickness of the layer applied superficially is in the range 10 nm to 5.0 m.

A micro power distribution box is provided which includes a device, a connector/housing and a cover. The device has a substrate, at least one first finger, at least one second finger, and at least one electrical component. The at least one first finger and the at least one second finger are electrically connected to one another. The at least one first finger has first, second and third portions. The at least one second finger has first and second portions. The substrate is overmolded to the first portions of the at least one first and second fingers. The substrate is not overmolded to the second portions of the at least one first and second fingers or to the third portion of the at least one first finger. The second portions of the at least one first and second fingers extend outwardly from the substrate. The second portion of the at least one first finger is a high current contact. The second portion of the at least one second finger is a contact pin. The third portion of the at least one first finger is exposed via an aperture provided through the substrate. The at least one electrical component is directly mounted to the third portion of the at least one first finger in order to electrically connect the at least one electrical component to the at least one first finger. The connector/housing is configured to house the device therein and is configured to be connected to a mating connector. The cover is configured to be secured to the connector/housing in a manner which prevents the device from being removed from the connector/housing.

Method for manufacturing an electronic component is provided. The method includes manufacturing elements that are produced by an additive manufacturing process. Moreover, the elements are produced in the same plane or out of plain with one or more foil substrates. The elements may be various structures, including, for example, connectors, electrical components (e.g., a resistor, a capacitor, a switch, and/or the like), and/or any other suitable electrical elements and/or structures.

A conductor path structure has a damping device for an oscillation-damped and/or vibration-damped (electronic, electromechanical, micromechanical) component. The conductor path structure has a first base body made of a carrier material including a connection area for receiving the component. The connection area is arranged separated from an area of the first base body surrounding it and is arranged oscillation-damped and/or vibration damped and co-acting with an intrinsic damping device of the conductor path structure. The conductor path structure includes a second base body arranged at a distance under the first base body, wherein above the second base body of the conductor path structure at least one adhesive layer of a damping material is provided. The intrinsic damping device is formed by said at least one adhesive layer arranged between the connection area of the first base body and the area of the second base body arranged below the connection area.

An elongated lead frame (100) for a plurality of solid state light emitters (116), an elongated lighting assembly and a method of manufacturing an elongated lead frame are provided. The elongated lead frame comprises a first patterned layer (310) of an electrically conductive material and a second patterned layer (320) of an electrically isolating material. The first patterned layer comprising two electrically conductive tracks (102) that comprise first structures (316, 316) for a first layer of a stack of light emitter islands and two electrically conductive connections between the first structures, at least one of the electrically conductive tracks comprises in between pairs of neighboring first structures a winded portion for forming a flexible electrically conductive connection in between the pairs of neighboring first structures. The second patterned layer comprising second structures for a second layer of the stack of the light emitter islands, the second patterned layer is provided on top of the first patterned layer.

Depicted embodiments are directed to an Application Specific Electronics Packaging (ASEP) system, which enables the manufacture of additional products using reel to reel (68a, 68b) manufacturing processes as opposed to the batch processes used to currently manufacture electronic products and MIDs. Through certain ASEP embodiments, it is possible to integrate connectors, sensors, LEDs, thermal management, antennas, RFID devices, microprocessors, memory, impedance control, and multi-layer functionality directly into a product.

A circuit board production method, the method comprising a process of disposing a circuit sheet on a substrate, the circuit sheet comprising circuits and a resin portion disposed at spaces between the circuits.

A method of manufacturing a circuit board includes: forming a plurality of metal electrodes so as to be separated from each other on a holding sheet by cutting a metal foil held on the holding sheet to remove a portion of the metal foil; forming adhesive layers on surfaces of the plurality of metal electrodes; adhering the adhesive layers to a base material by closely contacting the adhesive layers with the base material; and transcribing the adhesive layers and the plurality of metal electrodes onto the base material by detaching the holding sheet from the plurality of metal electrodes.

A circuit assembly includes a busbar substrate with busbars and a resin part that is in intimate contact with the busbars, a press-fit member that is made of metal with a thickness greater than the thickness of the busbars, and is press-fitted in the busbar substrate, an electronic component connected to the press-fit member, solder that connects the busbars and the press-fit member, and a solder accumulating portion that is formed with the resin part, and in which the solder is accumulated.