A capacitive discharge unit (CDU) for detonating an explosive in response to a control signal comprises a set of CDU components, including an exploding foil initiator (EFI), a trigger circuit, a firing capacitor, and an insulated-gate bipolar transistor (IGBT) firing switch. In various embodiments the components are arranged on a board for mechanically and electrically supporting the components in an ordered arrangement along a CDU axis where the CDU having an axial length defined by the ordered arrangement of two or more of the EFI, the firing capacitor, and the IBGT firing switch, wherein the trigger circuit is offset from the CDU axis such that the trigger circuit does not contribute to the axial length.

An image sensor module includes a circuit board, image sensor, electronic component assembly, and cable assembly. The circuit board includes a center section located between two end sections. The end sections each extend away from the center section and define an interior area there between. The image sensor is secured to an outer face of the circuit board in the center section with sensor contact fingers being connected at the circuit board outer face in one or both end sections. The electronic component arrangement is mounted on an inner face of the circuit board in the center section. A number of wires of the cable assembly extend through an end gap between the circuit board end sections and are connected to the inner face of the circuit board so as to overlap with the sensor contact fingers along a module longitudinal axis.

Disclosed are an improved structure for connecting printed circuit boards and display apparatus having the structure, by which two printed circuit boards are directly connected by a harness without extra parts. A structure for connecting printed circuit boards (PCBs), electrically connecting a first PCB and a second PCB with printed circuits provided thereon, the structure includes fixing holes formed in the first PCB and the second PCB, and a harness fixed to the fixing holes at both ends to electrically connect the first PCB and the second PCB, wherein the harness includes housings arranged in a pair to be fixed to the first PCB and the second PCB and having projections to be inserted and fixed to the fixing holes, contact terminals arranged in the housings to come into contact with the printed circuits, and a cable connected to the contact terminals to electrically connect the pair of housings.

A method provides a circuit carrier arrangement that includes: a cooling plate (1) which has spacer and fastening elements (3) for connection to a printed circuit board (2) in a spaced-apart manner; a printed circuit board (2) which has bores (4) for receiving spring element sleeves (9); at least one power semiconductor component (10) which is connected by a soldered connection to the printed circuit board (2) and fastening elements (3) in the state in which it is fitted with the cooling plate (1) by means of plug-in connections (11) of spring-action configuration; and at least one spring element (5) having at least two spring element sleeves (9) between which a web (6) that is connected to the spring element sleeves (9) extends, and supporting elements (7) arranged on either side of said web and at least one spring plate (8) being arranged on said web.

A shunt resistor module, which includes a shunt resistor having a resistor unit having a predetermined resistance, plate-shaped terminal units respectively configured to extend at both sides of the resistor unit, and a voltage measurement lead pin configured to protrude perpendicular to the terminal unit and having an end portion bent to be parallel to the terminal unit, and a PCB substrate having an assembly guide portion formed to be cut inward by a predetermined depth from an outermost side thereof. The voltage measurement lead pin is fit into the assembly guide portion so that the resistor unit and the terminal unit are placed on a front surface of the PCB substrate and the end portion of the voltage measurement lead pin is caught at a rear surface of the PCB substrate.

A power semiconductor component is specified, having a power semiconductor device arranged within a housing, wherein a heat sink is exposed on a first surface of the housing; a wiring substrate which receives the housing with the power semiconductor device and which has a first main surface and a second main surface. A heat dissipation region with increased thermal conductivity is arranged on the second main surface. The housing is arranged on the wiring substrate in such a way that the heat sink is connected to the heat dissipation region via a solder layer. A number of spacers which are arranged between the heat sink and the heat dissipation region are embedded in the solder layer. Furthermore, a method for producing a power semiconductor component is specified.

A work machine including a flow device for flowing molten solder from under a circuit board, and a backup pin for supporting the circuit board from below while a lead of a leaded component is being inserted into a through-hole, which are moved separately under the circuit board. Thus, when the circuit board needs to be supported, the backup pin can be moved to any position, and when solder needs to be applied, the backup pin can be moved to a position that does not obstruct operation of the flow device. Accordingly, as well as guaranteeing operation of the flow device, it is possible to support the circuit board with the backup pin as required, thus improving practicality of the work machine.

An electrical connection contact (5) for a ceramic component (2) is specified. The connection contact (5) comprises a first material (M1) and a second material (M2) arranged thereon, wherein the first material (M1) has a high electrical conductivity and the second material (M2) has a low coefficient of thermal expansion.

A printed circuit board includes a circuit trace and a connector pad. The connector pad provides electrical and mechanical mounting of a connector lead of a surface mount device and provides a circuit path between the surface mount device and the circuit trace. The connector pad includes 1) a connector pad base electrically coupled to the circuit trace, and 2) a first connector pad island electrically isolated from the connector pad base. The connector pad base has a length that is substantially equal to a length of a contact portion of the connector lead.

An electrical connection contact (5) for a ceramic component (2) is specified. The connection contact (5) comprises a first material (M1) and a second material (M2) arranged thereon, wherein the first material (M1) has a high electrical conductivity and the second material (M2) has a low coefficient of thermal expansion.