A SSD storage module comprising a printed circuit board (1), an encapsulating colloid (2), and an electronic circuit (3) welded on an inner surface of the printed circuit board (1) and having a data storage function; the encapsulating colloid (2) is formed on the inner surface of the printed circuit board (1) and is configured for seamlessly encapsulating the electronic circuit (3), an outer surface of the printed circuit board (1) is provided with a plurality of metal contact pieces (11), the plurality of metal contact pieces (11) are electrically connected with the electronic circuit (3), and the plurality of metal contact pieces (11) comprise a plurality of SATA interface contact pieces (110). The encapsulating colloid (2) seamlessly encapsulates the electronic circuit (3) and isolates the electronic circuit (3) from the air, such that a problem that the electronic circuit (3) is directly exposed to the air, and performances of components of the electronic circuit (3) may be affected, thereby resulting in an unstable functionality of a SSD can be avoided.

A connector for providing electronic communication with an electronic device is disclosed. The connector can comprise a substrate comprising layers of non-conductive material and conductive material. The connector can include an interface member mounted to the substrate and electrically connected with the conductor. A positive temperature coefficient (PTC) fuse can be embedded in the substrate and electrically connected with the conductor and the interface member. At least a portion of the PTC fuse can be disposed directly below the interface member.

A battery bridge for an electronic device, preferably for an electronic implant, has an electrically conductive first contact element, an electrically conductive second contact element and an insulator. The first contact element and the second contact element comprise a weldable material. In a first state of the battery bridge, the first contact element is distanced from the second contact element via a predefined air gap and the first contact element is electrically insulated from the second contact element by the air gap and the insulator. The battery bridge is formed in such a way that it can be transferred, by welding the first contact element and the second contact element together, into a second state, in which the air gap between the first contact element and the second contact element is closed electrically conductively, at least in part. A method for activating such an electronic device is also disclosed.

A control device suitable for use in a vehicle includes a circuit board and a thermal fuse holder including a removable spacer element and a plurality of breaker elements. The thermal fuse holder is attached at a terminal structure and, when the terminal structure is attached to the circuit board, the breaker elements engage the removable spacer element to hold the breaker elements at the circuit board. After terminals of the terminal structure and the breaker elements are soldered at the circuit board, the removable spacer element is removed from the thermal fuse holder, whereby the breaker elements are held at the circuit board via solder joints and are biased away from the circuit board. When the temperature at a respective solder joint exceeds a threshold temperature that melts the solder, the respective breaker element moves away from the circuit board to break the electrical connection at the solder joint.

Disclosed is a printed circuit board having at least one power semiconductor soldered thereon and, as a thermal fuse, a spring having two contact arms fastened to solder pads of the printed circuit board by soldered connections. The spring is under mechanical stress such that at least one of the two contact arms moves away from one of the solder pads by spring force as soon as the soldered connection loses its strength and fails due to overheating. The soldered connection of at least one of the contact arms loses its strength at a lower temperature and is formed from a different alloy than the soldered connection that connects the power semiconductor to the printed circuit board. A method for populating a printed circuit board is also described.

A connector-fitting structure of flexible printed circuit includes: a flexible printed circuit on which a wiring pattern is formed; an electronic component connected to the wiring pattern of the flexible printed circuit; and a connector to which one end part of the flexible printed circuit is fitted. The one end part of the flexible printed circuit is fitted to the connector to cause the electronic component to be housed in the connector.

A connector for providing electronic communication with an electronic device is disclosed. The connector can comprise a substrate comprising layers of non-conductive material and conductive material. The connector can include an interface member mounted to the substrate and electrically connected with the conductor. A positive temperature coefficient (PTC) fuse can be embedded in the substrate and electrically connected with the conductor and the interface member. At least a portion of the PTC fuse can be disposed directly below the interface member.

A flexible printed circuit board including an electronic component includes a flexible printed circuit board, an electronic component, a cover, and a restricting portion. The printed circuit board including an electrically conductive line. The electronic component is mounted on the flexible printed circuit board and joined to the electrically conductive line. The cover covers a joint between the electronic component and the electrically conductive line. The restricting portion is along an outer edge of the cover. The flexible printed circuit board includes a groove along the outer edge of the cover. The groove is defined by opposed groove side surfaces. One of the opposed groove side surfaces farther from the electronic component is defined as the restricting portion.

An electrical assembly is presented herein. The electrical assembly includes a first printed circuit board having a planar first substrate and a first conductive trace disposed thereon, a second printed circuit board distinct from the first printed circuit board, the second printed circuit board having a planar second substrate and a second conductive trace disposed thereon, and an electrically conductive device having at least two terminals interconnecting the first conductive trace to the second conductive trace. A method of assembling an electrical distribution center is also presented.

An electronic assembly, has at least one circuit board with conductor tracks, at least one current-limiting arrangement in the form of a thermal predetermined breaking point in at least one of the conductor tracks, and a fire-containment device in the region of the current-limiting arrangement.