The present disclosure provides a flexible display module and a method for manufacturing the flexible display module. The flexible display module includes a flexible display panel, a driving chip and a circuit board. The flexible display panel includes a display region and a bonding region, and the driving chip and the circuit board are arranged at the bonding region. The circuit board includes a first flexible printed circuit and a first printed circuit board provided with an electronic element, the first printed circuit board is coupled to one end of the first flexible printed circuit, and the first flexible printed circuit includes a bonded portion coupled to the bonding region of the flexible display panel. The first flexible printed circuit is bent so that a first space is defined by the first flexible printed circuit, the first printed circuit board and the flexible display panel.

An interconnect for connecting a first electronic circuit to a second, external stretchable electronic circuit device comprises: conductive lines of the first electronic circuit arranged in a plane; connectors configured to define an overlap in the plane between each end of the conductive lines with a corresponding end of stretchable conductive lines providing an electrical connection between the conductive lines and the stretchable conductive lines over the entire overlap; and at least one anchoring structure for providing an anchoring of the first electronic circuit with the second, external stretchable electronic circuit device, wherein the at least one anchoring structure provides anchoring transverse to the plane in anchoring positions on opposite sides of the overlap.

The disclosure relates to an auxiliary module for an electrical switching device including an input, an output, a first housing and a switching module which is configured to switch between a first configuration in which the switching module allows a current to flow between the input and the output and a second configuration in which the switching module blocks the current, the first housing defining a chamber which accommodates the switching module and defining a space for receiving the auxiliary module, the space containing a signalling member configured to transmit information relating to a state of the electrical switching device to the auxiliary module when the auxiliary module is in the space. This auxiliary module comprises a controller configured to generate a message and a radiofrequency communication module configured to transmit the message, via a radiofrequency data link, to a remote device.

The disclosure relates to an auxiliary module for an electrical switching device including an input, an output, a first housing and a switching module which is configured to switch between a first configuration in which the switching module allows a current to flow between the input and the output and a second configuration in which the switching module blocks the current, the first housing defining a chamber which accommodates the switching module and defining a space for receiving the auxiliary module, the space containing a signalling member configured to transmit information relating to a state of the electrical switching device to the auxiliary module when the auxiliary module is in the space. This auxiliary module comprises a controller configured to generate a message and a radiofrequency communication module configured to transmit the message, via a radiofrequency data link, to a remote device.

An electronic device includes a middle frame, a first flexible printed circuit FPC, a second FPC and a battery. Projections of the first FPC and the second FPC on the middle frame have a first overlapping region. The first overlapping region is located inside a projection of the battery on the middle frame and is far away from an edge of the battery. A first through hole is disposed on the middle frame. The first overlapping region is located in the first through hole. The electronic device provided in this application can implement reduction of an overall thickness, so that the electronic device provides better user experience.

An integral toolless-installation Compression Attached Memory Module (CAMM) bolster plate has a generally flat, parallelepiped body portion configured to contact one surface of a CAMM Printed Circuit Board (PCB) and provide compression between the CAMM and a z-axis compression connector. The bolster plate body defines (a) ramped keyhole(s), each ramped keyhole converts lateral displacement of the toolless-installation CAMM bolster plate into vertical displacement, providing the compression between the CAMM and the z-axis compression connector, by the ramped keyhole(s) sliding along (a) bottom face(s) of (a) head(s) of (a) fixed standoff(s) extending from an information handling system (IHS) PCB, through the z-axis compression connector and the CAMM PCB. The integral toolless-installation CAMM bolster plate may lock in place, laterally displaced, to maintain the compression between the CAMM and the z-axis compression connector. The integral toolless-installation CAMM bolster plate may also have a flange portion extending generally perpendicular from the body portion.

An optoelectronic apparatus (200) and an optoelectronic integration method are disclosed, so that bandwidth for signal transmission can be improved, and signal transmission performance is improved. The optoelectronic apparatus (200) includes: a printed circuit board PCB (201), where a first substrate (203) and a second substrate (205) are separately disposed on the PCB (201), an application specific integrated circuit ASIC (202) is disposed on the first substrate (203), and an optoelectronic component (204) is disposed on the second substrate (205); and a flexible printed circuit FPC (206), where a first end of the FPC (206) is disposed on an upper surface of the first substrate (203) and is electrically connected to the ASIC (202), and a second end of the FPC (206) is disposed on the second substrate (205) and is electrically connected to the optoelectronic component (204).

An electronic device is provided. The electronic device includes a frame, a first partition wall protruding from the frame in a first direction and dividing the frame into a first area and a second area, a second partition wall portion protruding from the frame in the first direction and dividing the frame into a second area and a third area, a first printed circuit board disposed in the first area, a battery disposed in the second area, a second printed circuit board disposed in the third area, and a display circuit including at least two flexible printed circuit boards. The flexible printed circuit boards include an overlapping area in which at least some areas overlap, the overlapping area being disposed in the second area, and, in the frame, an opening is formed in a portion facing the overlapping area.

An electronic device is provided. The electronic device includes a frame, a first partition wall protruding from the frame in a first direction and dividing the frame into a first area and a second area, a second partition wall portion protruding from the frame in the first direction and dividing the frame into a second area and a third area, a first printed circuit board disposed in the first area, a battery disposed in the second area, a second printed circuit board disposed in the third area, and a display circuit including at least two flexible printed circuit boards. The flexible printed circuit boards include an overlapping area in which at least some areas overlap, the overlapping area being disposed in the second area, and, in the frame, an opening is formed in a portion facing the overlapping area.

A display device includes a display panel, a support member disposed under the display panel, a circuit board electrically connected to the display panel and disposed under the support member, and a metal sheet disposed between the circuit board and the support member, bonded to the circuit board by a first adhesive film, and bonded to the support member by a second adhesive film.