An inter-device cabling movement system includes a base and a plurality of cable attachment devices that extend from the base in a port identification sequence. Each of the plurality of cable attachment devices includes a cable engagement element that is configured to engage a respective cable, and a cable securing element that is configured to secure the cable engagement element to the respective cable. The cable engagement elements and cable securing elements may be utilized to secure each cable attachment device to respective cables connected to first ports on a first device so that those respective cables may be disconnected from the first pots on the first device and reconnected to second ports on a second device based on the port identification sequence.

A pushing mechanism, configured to be disposed on a case body, includes a fixed component, a slidable component and a pushing component. The slidable component is disposed on the fixed component and includes a connection plate and a guiding plate. The guiding plate protrudes from the connection plate and has a first supporting portion, a second supporting portion and an inclined guiding portion connected to the first supporting portion and the second supporting portion. The first supporting portion is closer to the connection plate than the second supporting portion. The pushing component is disposed on the fixed component. A slidable direction of the pushing component differs from a slidable direction of the slidable component. When the slidable component is moved relative to the fixed component, the pushing component is guided by the guiding plate to slide between the first supporting portion and the second supporting portion.

A computer chassis includes a mounting hub configured to be coupled between a display device and a computer support structure and a chassis frame configured to be removably received by the mounting hub. In some examples, the chassis frame comprises a central bracket and a pair of frame arms extending from the central bracket. Each frame arm may be configured to support one or more computer components in a customizable arrangement. The central bracket may include a channel configured to receive a cable connecting a computer component attached to a first one of the frame arms to a computer component attached to a second one of the frame arms. At least a portion of the cable management channel may be disposed between the portions of the mounting hub configured to couple to the display device and computer support structure respectively.

The present application discloses an electronic device and a connection module therefor. The connection module includes a first connection piece (1) and a second connection piece (2); side walls of the first connection piece (1) is each provided with notches and a limiting end which are connected to each other and are arranged at an angle; the second connection piece (2) is provided with limiting pieces (12) adapted to be placed at the limiting ends by means of the notches; one of the first connection piece (1) and the second connection piece (2) is provided with a retractable positioning assembly, and the side walls of the other are provided with positioning holes (10) fastening the retractable positioning assembly, so that when the limiting pieces (12) are placed at the limiting ends, the retractable positioning assembly is fastened in the positioning holes (10). According to the connection module, quick assembly is allowed, the connection is reliable, and the problem of falloff caused by relative movement of a plurality of connection pieces in a connection module is solved.

An electronic device includes an enclosure formed of a plurality of layers cooperating to define an interior volume. The enclosure includes a first layer formed of a first material and defining a user input surface of the enclosure and a first portion of a side surface of the enclosure. The enclosure also includes a second layer, formed of a second material different from the first material, positioned below the first layer and defining a second portion of the side surface of the enclosure. The enclosure also includes a third layer, formed of a third material different from the first and second materials, positioned below the second layer and defining a bottom surface of the enclosure and a third portion of the side surface of the enclosure.

A two-parts shell or housing assembly not requiring a pressure jig for assembly includes an upper shell and a lower shell. The upper shell includes a first surface and a second surface. Hooks are disposed on edges of the second surface. The lower shell includes an inner bottom surface and a first blocking surface. A stepped portion is formed at the connection portion between the inner bottom surface and the first blocking surface. The stepped portion includes a first side and a second side. The upper shell is disposed on the second side. The first side defines slots corresponding to the hooks. A receiving space is formed by the hook, the stepped portion, and the second side for receiving adhesive. An electronic device is also provided.

A frame includes a support assembly extending in a first direction, two hemming brackets, and at least two detachable fixing structures. The hemming brackets respectively disposed at both sides of the support assembly in the first direction. Each hemming bracket extends in a second direction different from the first direction. An end of the hemming bracket away from the support assembly is a flanged portion. The hemming bracket is fixed to a corresponding end of the support assembly through at least one detachable fixing structure. One of the hemming bracket and the end of the support assembly has at least one via hole, and each detachable fixing structure passing through a via hole to be fixed to another of the hemming bracket and the end of the support assembly. An outer wall of the detachable fixing structure and a hole wall of the via hole has a gap therebetween.

The embodiments include a stackable computing device that includes an integrated heatsink and antenna structure and a housing structure. The housing structure includes a housing casing that surrounds the integrated heatsink and antenna structure. The integrated heatsink and antenna structure includes a heatsink base and one or more radio frequency (RF) antenna portions. The heatsink base includes a connector port that provides an interface between components of the computing device and other computing or peripheral devices. For example, the heatsink base may include platform that is configured to have circuitry fixedly secured on a first side of the platform with a connector of the circuitry aligned with an aperture of the connector port such that a connection to the circuitry is accepted by circuitry of another computing device.

An expansion card support device includes an arm configured to rotate between a closed position and an open position relative to an interior surface of a computer housing opposite from one or more interface buses. The arm is substantially parallel to the interior surface in the closed position and substantially perpendicular to the interior surface in the open position. The arm is sized so as to abut edges of one or more expansion cards retained in the one or more interface buses with the arm in the open position. The device further includes a first spring configured to rotate the arm from the closed position to the open position. The device further includes a latch configured to maintain the arm in the closed position with the latch in a latched state.

Examples described herein relate to a latch for releasably coupling objects. In some such examples, the latch includes a receiver, a torque member, and a handle. The receiver includes a lobe to releasably engage an anchor point within a recess of the receiver. The torque member is rotatably coupled to the receiver to rotate the receiver. The handle includes a torque portion rotatably coupled to the torque member to rotate the torque member and includes a lever extending from the torque portion.