Disclosed is a computing device, comprising a frame, a computing apparatus, a controller, a power source and a heat dissipation device, wherein the computing apparatus is arranged in the frame and comprises a power source interface; the power source comprises a power source connection end, and also comprises a connection box connected to the frame; the power source interface extends from the frame into the connection box; the power source connection end extends into the connection box; and the power source interface and the power source connection end are connected in the connection box via one or more conducting bars.

A baffle assembly includes a frame, a protruding piece and a baffle structure. The frame is configured to accommodate some expansion cards. The frame includes a first surface and a second surface adjacent to the first surface. The first surface has an opening configured to allow the expansion cards to enter into the frame. The protruding piece protrudes from the first surface. The baffle structure includes a first blocking plate and a second blocking plate. The first blocking plate is configured to abut against the first surface and at least partially cover the opening. The first blocking plate has a through hole. The through hole extends along a first direction. The protruding piece at least partially penetrates through the through hole. The second blocking plate is connected with the first blocking plate along the first direction and is configured to abut against the second surface.

A rack-mountable computer system directs separate portions of a cooling airflow from an inlet air plenum in the computer system interior through separate air passages to remove heat from separate portions of a set of heat-producing components. The air passages can preclude a portion of cooling airflow removing heat from a component from being preheated by another component. Plenums and air passages can be established through the arrangement of components in the interior. Components can be arranged in progressive offsets throughout the depth of the interior to vary plenum flow area throughout the depth, which can progressively impede and redirect airflow through the inlet plenum into the air passages. Arrangements can include an angled row, a staggered configuration, etc. The computer system can include a chassis which can translate, while maintaining operation of hot-pluggable electronic components coupled throughout the depth, to enable swapping of hot-pluggable electronic components throughout the interior.

A carrier tray to allow rapid installment of additional modules or devices, without screws, into a computer includes a frame, two sliders, an elastic member, and a handle. A bracket of the frame has a unit cavity. The two sliders can slide along a first direction and the elastic member is compressible between the two sliders. The handle allows pushing and pulling of the tray along a second direction and is attached to the two sliders, the two sliders can move towards each other (to a first position) or apart (to a second position). The two sliders return to the unity cavity by pulling the handle from the first position to the second position along the second direction. Continued pulling of the handle in the second direction removes the carrier tray from the computer.

A removal mechanism of the daughter board includes a fixed frame, a moving frame, a moved frame and a handle. The fixed frame has a pushed portion. The moving frame is movably coupled to the fixed frame and has an oblique tapered edge. The moved frame is fixed to the daughter board and has a corresponding oblique edge. The handle is rotatably connected to the moving frame and has a pushing portion, and the pushed portion is on a rotation path that the pushing portion rotates with the handle. When the handle is operated, the pushing portion pushes the pushed portion, the moving frame moves relative to the fixed frame to push the corresponding oblique edge by the oblique tapered edge. The moved frame drives the daughter board to be removed from the connector.

An interface card assembly adapted for fixing an M.2 interface card to a circuit board body with an M.2 connector is provided. The M.2 interface card includes a connecting end and an end. The interface card assembly includes a heat dissipation plate and a fastener. The heat dissipation plate is disposed at a position adjacent to the M.2 connector, and the heat dissipation plate includes a hole. The fastener is detachably disposed in the hole. The fastener includes a main body and a cantilever, and a clamping part is disposed between the main body and the cantilever. When the M.2 interface card is inserted into the M.2 connector through the connecting end, the fastener moves relative to the heat dissipation plate at the end, so that the M.2 interface card extends into the clamping part and is clamped between the main body and the cantilever.

A scalable graphics card assembly support system for a desktop chassis comprises an end support for coupling to an end of a graphics card assembly and a side support for coupling to a side of the card assembly. The side support can be coupled to any of several positions in a retention guide and the end support may couple to the card assembly or an extension coupled to the graphics card assembly, allowing the graphics card assembly support system to support graphic card assemblies of different lengths, widths and thicknesses. The graphics card assembly support system couples to one or more selected points within the chassis such that a chassis panel can be easily removed for servicing the information handling system. Cable parking connectors and conduit couplers provide better cable and conduit management for a more aesthetically pleasing appearance of an information handling system in the chassis.

A locking mechanism is provided. The locking mechanism includes a base, a connecting rod, a fastener, and a linking member. The connecting rod and the fastener penetrate the base and are rotatable relative to the base. The connecting rod and the fastener are disposed parallel to each other. The linking member is connected to the connecting rod and the fastener, and is configured to link up the connecting rod and the fastener. Accordingly, the locking mechanism may be suitable for an expansion device with a specific size, and therefore the performance and the design flexibility of the electronic apparatus may be enhanced.

A system and method of implementing an adaptable graphics board form factor design comprising an adaptable graphics board including a reconfigurable zone subset of components including a reconfigurable I/O module having display data ports disposed along a first edge of the adaptable graphics board, the adaptable graphics board including a set of core components including the graphics processor and graphics memory, wherein the reconfigurable zone subset of components are orientable relative to the set of core components to interface with an information handling system chassis of a first model specification selected from a plurality of model specifications for information handling systems in which the adaptable graphics board may be used, and the adaptable graphics board including a connector pad interface area for receiving an array of compressible electrical spring contacts of a compression jumper pad for a flexible compression jumper connector, wherein the connector pad interface area is disposed along a second edge of the adaptable graphics board for alignment adjacent to a motherboard to be operatively coupled via the flexible compression jumper connector in the information handling system.

A partition for separating computer components in an apparatus holding the computer components is provided. The partition includes a body with a first side and a second side; one or more top tabs projecting from both the first side and the second side of the body; one or more bottom tabs projecting from the first side of the body; and one or more bottom protrusions projecting from the second side of the body. The one or more top tabs are secured in a first manner, e.g., through rivets, to a first panel of the apparatus. The one or more bottom tabs are secured in the first manner to a second panel of the apparatus. The one or more bottom protrusions are secured in a second manner to the second panel of the apparatus, e.g., tucking a protrusion under the second panel. The features allow different-sized compartments for different storage form factors.