A bracket for mounting a processor and a support structure for receiving bracket-supported processors for cluster computing are provided. In some embodiments, a bracket may be configured to receive a processor and fasten the processor to the bracket. The bracket may be configured to mount the processor to a support structure. The support structure may be configured to receive an array of brackets. The support structure may be configured to be stacked in combination with additional support structures.

A control device includes a casing and a control circuit substrate arranged inside the casing. The control circuit substrate includes: a control circuit mounted on the control circuit substrate; an internal connector connectable to a communication cable inside the casing, the communication cable being connected to an expansion circuit substrate; and an external connector connectable to another communication cable outside the casing, the another communication cable being connected to another expansion circuit substrate. The control circuit is connected to the internal connector and the external connector in parallel.

A detachable structure for shielding input/output (I/O) ports of a motherboard includes a housing and a blocking plate. The housing has a plurality of installed portions, an internal space, and an opening, the internal space communicates with the opening, and the plurality of installed portions are arranged in the internal space. The housing is arranged on the motherboard, and the internal space accommodates the I/O ports. The blocking plate is penetrated with a plurality of first holes. A plurality of installing elements are respectively fixed to the installed portions to fix the blocking plate to the housing, thereby shielding the opening. The positions of the plurality of first holes respectively correspond to the positions of the I/O ports to use the plurality of first holes to expose the I/O ports.

A bracket for mounting a processor and a support structure for receiving bracket-supported processors for cluster computing are provided. In some embodiments, a bracket may be configured to receive a processor and fasten the processor to the bracket. The bracket may be configured to mount the processor to a support structure. The support structure may be configured to receive an array of brackets. The support structure may be configured to be stacked in combination with additional support structures.

A system includes a processor, such as a CPU, surrounded by high-density memory with lower profile than a standard DIMM. The low profile, high-density memory provides multiple memory channels for the processor. With the memory configuration, the system can maintain the memory configurability with increased density and increased memory channels for the processor.

A bracket for mounting a processor and a support structure for receiving bracket-supported processors for duster computing are provided. In some embodiments, a bracket may be configured to receive a processor and fasten the processor to the bracket. The bracket may be configured to mount the processor to a support structure. The support structure may be configured to receive an array of brackets. The support structure may be configured to be stacked in combination with additional support structures.

A chassis structure including a box body is provided. The box body includes a main plate and a plurality of side plates. The main plate includes a hollow region and a bent component adjoining to the hollow region, wherein the bent component includes a folded edge connected to the hollow region. The side plates surround a periphery of the main plate and define an accommodating space. Therefore, manufacturing costs are saved, a manufacturing process is simplified, and smoothness and neatness in appearance are maintained.

An independent graphics card system comprises an expansion motherboard, a system power supply, at least one expansion graphics card and a fan assembly. The system power supply is electrically connected to the expansion motherboard. The at least one expansion graphics card is plugged into the expansion motherboard through an adapter card. The at least one expansion graphics card is parallel with the expansion motherboard. The fan assembly dissipates heat of the at least one expansion graphics card.

A server includes an adapter device, multiple storage modules and multiple controllers. The adapter device includes a base circuit board having opposite first and second surfaces, multiple first connectors disposed on the first surface along a first direction and connected to the base circuit board, and multiple second connectors disposed on the second surface along the first direction in pairs, each of which is arranged along a second direction, is connected to the base circuit board and is disposed between adjacent two of the first connectors. Each of the storage modules is connected to a corresponding first connector. Each of the controllers is connected to a corresponding second connector.

Securing a riser cage and/or electronic components coupled thereto within an information handling system can be accomplished using a riser cage apparatus. The riser cage may be configured to removably secure the electronic components to a surface of the information handling system using one or more fasteners configured to couple the riser cage to a surface of a chassis. The one or more fasteners may comprise a protrusion configured to engage a pin coupled to the surface. The protrusion of the one or more fasteners may be movable relative to the riser cage between a first locked position in which the pin coupled to the surface is engaged by the protrusion and a second unlocked position in which the pin coupled to the surface is not engaged by the protrusion.