A chassis includes a housing of an expansion card receiver adapted to house an expansion card and limit removal of the expansion card to a removal path; and a card holder of the expansion card. The card holder, while a retention member of the card holder is disposed in the removal path, receives a translation force directed away from the expansion card along the removal path; in response to receiving the translation force: translates the retention member along the removal path away from the expansion card until the retention member reaches a translation limiter to transition the retention member from a translatable state to a rotatable state, while the retention member is in the rotatable state and not in the translatable state: receives a rotation force directed out of the removal path; and in response to receiving the rotation force, rotate the retention member out of the removal path.

A case for receiving at least one electronic device is provided, including a housing, a hinge, a locking member, and a cover. The housing has an accommodating space and an opening communicated with the accommodating space. The hinge is slidably connected to the housing. The cover has an upper side, a lower side, and an outer surface. The lower side is pivotally connected to the hinge. When the locking member affixes the upper side to the housing and the hinge is in a first position relative to the housing, the cover is disposed between an environment space and the accommodating space, and the outer surface faces the environment space. When the locking member is released and the hinge moves to a second position relative to the housing, the cover leaves the position between the environment space and the accommodating space, and the outer surface faces the environment space.

Embodiments are generally directed apparatuses, methods, techniques and so forth determine an access level of operation based on an indication received via one or more network links from a pod management controller, and enable or disable a firmware update capability for a firmware device based on the access level of operation, the firmware update capability to change firmware for the firmware device. Embodiments may also include determining one or more configuration settings of a plurality of configuration settings to enable for configuration based on the access level of operation, and enable configuration of the one or more configuration settings.

A circuit card assembly comprising at least one electronic component that generates heat and a thermal management system the at least one electronic component is disclosed. The thermal management system comprises one or more phase change modules for distributing and storing heat; a metal frame in thermal contact with the at least one electronic component and having at least one opening for receiving the one or more phase change modules; and a heat transfer apparatus in thermal contact with one or more of the at least one electronic component and the metal frame. The heat transfer apparatus comprises at least one heat pipe and/or at least one heat spreader. The heat transfer apparatus provides a first heat transfer path during a period of reduced heat dissipation or cooling. The one or more phase change modules distributes and stores heat during the period of reduced heat dissipation or cooling.

A connection structure for attaching a first electronic device onto a second electronic device is disclosed. The connection structure comprises an action unit and an assist unit, wherein the action unit and the assist unit are particularly designed to be cooperated to each other in case of connecting the first electronic device to the second electronic device. After the first electronic device is attached to the second electronic device through the connection structure, a first electrical connection portion of an electronic card is inserted into an electronic card slot in the first electronic device, and a second electrical connection portion of the electronic card is inserted into an electronic card slot in the second electronic device, thereby making the two electronic devices communicate with to each other through the electronic card. As a result, the function(s) of the first electronic device is expended.

Disclosed is an industrial control device including a point-to-point backplane/point module architecture providing RIUP (Removal and Insertion Under Power) functionality where data communications between modules is maintained after the removal of a point module from the backplane. According to an exemplary embodiment, a backplane includes a plurality of passive mechanical bypass switches controlled by the insertion and removal of respective point modules, whereby data communicated bypass a removed point module interface and point-to-point data communications are provided to an inserted point module after an initial routine is executed by a microcontroller associated with the inserted point module.

A server includes a casing, a frame, at least one movable carrier and at least one M.2 expansion card. The casing has a through hole. The frame has an opening and an accommodation space connected to the opening. The frame is fixed in the casing and the opening corresponds to the through hole, so that the accommodation space is exposed to exterior via the through hole. The at least one movable carrier is removably disposed in the accommodation space, and the at least one M.2 expansion card is disposed on the movable carrier.

An electronic assembly including motherboard, first slide rail, second slide rail, expansion card and engagement component. Motherboard includes main circuit board and first connector. First and second slide rails are fixed on main circuit board. First slide rail has first engagement hole. Expansion card includes expansion circuit board and second connector. Expansion circuit board is disposed on first and second slide rails and has first positioning recess. Second connector is plugged into first connector. Engagement component includes connecting portion, first movable end portion, second movable end portion, first protruding portion, and second protruding portion. First and second movable end portions are respectively connected to two opposite sides of connecting portion. First protruding portion protrudes from first movable end portion and is removably engaged with first positioning recess. Second protruding portion protrudes from second movable end portion and is removably engaged with first engagement hole.

Technologies for dynamically managing resources in disaggregated accelerators include an accelerator. The accelerator includes acceleration circuitry with multiple logic portions, each capable of executing a different workload. Additionally, the accelerator includes communication circuitry to receive a workload to be executed by a logic portion of the accelerator and a dynamic resource allocation logic unit to identify a resource utilization threshold associated with one or more shared resources of the accelerator to be used by a logic portion in the execution of the workload, limit, as a function of the resource utilization threshold, the utilization of the one or more shared resources by the logic portion as the logic portion executes the workload, and subsequently adjust the resource utilization threshold as the workload is executed. Other embodiments are also described and claimed.

An electronic device having slots into each of which a circuit board is inserted includes faceplates attached respectively to the circuit boards on the side of an extraction direction. The faceplates each include two handle portions that are disposed respectively at both ends of a main body in the width direction and that extend in the extraction direction. The handle portion of one of two faceplates adjacent in the width direction that is located closer to the other of the faceplates, and the handle portion of the other faceplate that is located closer to the one faceplate, have respective distal ends shifted from each other in a thickness direction.