A heat radiation structure for an electric device includes: at least one multi-layer substrate including a plurality of base parts made of insulation material and a conductor pattern, which are stacked in a multi-layer structure so that the conductor pattern is electrically coupled with an interlayer connection portion in the base parts; the electric device having at least one of a first electric element built in the at least one multi-layer substrate and a second electric element, which is not built in the multi-layer substrate; and a low heat resistance element opposed to the electric device. The low heat resistance element has a heat resistance lower than the insulation material.

The present invention provides a device for conditioning semiconductor chips and a corresponding test method. The device comprises a chip temperature control means for receiving a semiconductor chip or a plurality of semiconductor chips and comprises a base body which can be flushed with a fluid for temperature control and which comprises a corresponding number of recesses which extend from a front face to a rear face of the base body; a corresponding number of chip bonding pedestals which are inserted, in thermal contact with the base body, into the recesses which comprise a chip receiving region on the front face and a wiring means on the inside which is constructed for supplying electrical signals from and/or to the semiconductor chip inserted in the respective chip receiving region; and a motherboard attached to the rear face in such a way that the wiring means of the chip bonding pedestals is electrically connected to a wiring means of the motherboard.

A transmitter and a method for mounting a transmitter on a panel, wherein the panel is a door or wall of an electrical cabinet, a display panel, a control panel or a diaphragm, wherein the transmitter includes a display module and a computer module, wherein the display module includes at least a first securement means and a cable, and the display module is connectable via the cable with the computer module. The method comprises the steps of: drilling at least a first hole in the panel, wherein the first hole is less than the area of the display module lying against the panel bringing the cable from a first side of the panel through the first hole to a second side of the panel securing the display module to the panel using a second securement means complementary to the first securement means securing the computer module to the second side, and connecting the computer module with the display module via the cable.

The present invention relates construction element comprising: a sandwich structure comprising an electrically insulating layer and an electrically conducting front layer and an electrically conducting rear layer which are spaced apart by the electrically insulating layer. A circuit board is carrying an electronic component and is positioned between the electronic component and the electrically conducting rear layer. The electronic component comprising a first and a second electrical terminal, wherein the first electrical terminal is in electrical connection with the electrically conducting front layer, and the second electrical terminal is in electrical connection with the electrically conducting rear layer.

A filtered feedthrough assembly for an implantable medical device comprises a ferrule, an electrical insulator coupled to the ferrule by a connection element, a plurality of feedthrough conductors extending through the electrical insulator, a printed circuit board (PCB), and plurality of capacitors. The PCB is coupled to the ferrule or the electrical insulator, and includes one or more ground layers and a plurality of vias. The connection element is electrically coupled to the ground layer through the vias. The capacitor has a ground terminal electrically coupled to the ground layer through at least one of the vias, and a conductor terminal electrically coupled to the feedthrough conductor.

A position and orientation of an electronic component attitude are recognized, a mounting head is moved above the electronic component, a rotator is horizontally rotated so that a lower surface of the electronic component is oriented in a direction opposite to a pusher, the electronic component of the fallen-down attitude is sucked and held by the nozzle by lowering a component holder, a attitude of the electronic component that is held is changed to a stand-up attitude by vertically rotating the component holder, leads of the electronic component of which the attitude is changed to the stand-up attitude and insertion holes of the substrate into which the leads are inserted are positioned, and the leads are inserted into the insertion holes of the substrate by pushing the electronic component toward the substrate by causing the pusher to abut against an upper surface of the electronic component of the stand-up attitude.

A component built-in board of multi-layer structure that has a plurality of unit boards stacked therein and is configured having a plurality of electronic components built in thereto in a stacking direction, wherein the plurality of unit boards include: a double-sided board that includes a first insulating layer, a first wiring layer formed on both surfaces of the first insulating layer, and a first interlayer conductive layer that penetrates the first insulating layer and is connected to the first wiring layer, and that comprises an opening in which the electronic component is housed; and an intermediate board that includes a second insulating layer, a first adhesive layer provided on both surfaces of the second insulating layer, and a second interlayer conductive layer that penetrates the second insulating layer along with the first adhesive layer, and the double-sided board is disposed above and below the intermediate board.