The present invention provides a computing device, apparatus for holding a power supply device, and methods of installing a power supply device in the computing device. The apparatus comprises a container and at least one electrical contact disposed on the container. The container is configured to hold the power supply device and to be received in a receiving space defined by the computing device. The container, when received in the receiving space, is operable to be removed from the receiving space without necessity of opening a cover of the computing device. The apparatus, computing device, and methods are advantageous in various aspects such as being favorable to the lifetime of the power supply device, convenient for uses to manage the power supply device, such as monitoring the status and make replacement when necessary, etc.

This disclosure relates to a supercapacitor carrier configured to accommodate a supercapacitor and to be connected to a connector. The supercapacitor carrier includes a support component, a holder, and a baffle. The support component includes a substrate part and an insertion part. The substrate part is connected to the insertion part. The insertion part is configured to be inserted into the connector. The holder includes a main plate and a first side plate that are spaced apart from each other and form an accommodation space therebetween. The accommodation space is configured to accommodate the supercapacitor. The first side plate is connected to the main plate, and the first side plate is disposed on the substrate part. The baffle is disposed on the substrate part. The baffle and the insertion part are located at different sides of the substrate part.

A power backplane assembly is adapted to be connected to a power supply. The power supply outputs a first voltage. The power backplane assembly includes a backplane body, a conversion circuit board, and an output circuit board. The backplane body is for plugging in the power supply. The conversion circuit board is electrically connected to the backplane body. The backplane body is adapted to deliver the first voltage to the conversion circuit board. The conversion circuit board converts the first voltage into a second voltage. The output circuit board is electrically connected to the conversion circuit board and includes a first output connector and a second output connector. The first output connector is configured to output the first voltage, and the second output connector is at least configured to output the second voltage. A power supply module which has the power backplane assembly is also provided.

An assembly for a computer system includes an insert housing with a housing floor; a power supply unit arranged on the housing floor and having a plug contact; a main circuit board arranged within the insert housing substantially parallel to the housing floor; and an angle plug having a mating plug contact and a connection region for connection of the power supply unit to the main circuit board, wherein the angle plug, when connected to the main circuit board via the connection region, connects to a top face of the main circuit board at a first installation height of the main circuit board and connects to a bottom face of the main circuit board at a second installation height of the main circuit board so that height compensation with respect to the plug contact of the power supply unit is established in each case.

The present disclosure includes apparatuses and methods for providing energy information to memory. An embodiment includes determining, by a host, that a charge level of an energy source coupled to the host has reached or exceeded a threshold value, and transmitting, from the host to a memory device coupled to the host, signaling indicative of an energy mode for the memory device, wherein the signaling is transmitted based at least in part on determining that the charge level of the energy source has reached or exceeded the threshold.

Power systems and methods of using the same to deliver power. A power system referenced herein can include a housing capable of attaching to a workstation, one or more cradles or mounting fixtures to receive at least one energy storage device, electronic circuitry to communicate status of the at least one energy storage device, state of charge of the at least one energy storage device, and/or overall health of the at least one energy storage device, and one or more electrical connectors to allow the at least one energy storage device to charge and/or discharge and communicate with the electronic circuitry, with said housing having an internal power supply and charge circuitry, said power supply capable of receiving input power from an external AC or DC power source; wherein the power system is configured to deliver power to the workstation.

A quick releasing device, which is adapted to be fixed in or removed from a slot of a casing, is provided. The quick releasing device includes a frame, an arm and a handle. The frame has a hole. The arm is disposed at one side of the frame and a part of the arm corresponds to the hole. The handle is rotatably disposed at another side of the frame to rotate between a working position and a retracting position. The handle includes a pressing member whose position corresponds to the hole. The pressing member of the handle passes through the hole of the frame and pushes the arm when the quick releasing device is inserted into the slot of the casing and the handle is rotated from the working position to the retracting position, deforming the arm and interfering with a wall surface of the casing beside the slot.

Apparatus and methods employing twisted differential compensation for routing high-speed signals near power delivery inductors. Traces used for a high-speed differential signal including a P trace and an N trace are routed through one or more layers in a multi-layer printed circuit board (PCB) substrate and employ a twisted portion proximate to the centerline of an inductor under which portions of the P and N traces are swapped horizontally in a layer parallel to the top plane and/or are swapped vertically by swapping layers. The signal paths are routed such that a level of noise inductively coupled into the P trace and the N trace from the inductor is approximately equally. Stripline structures may be used for signals that are routed under an inductor, while stripline and microstrip structures may be used for signals routed adjacent to an inductor.

An electronic apparatus includes a flexible printed circuit board having a main body on which wiring pattern is formed, a connector having a connection terminal connected to the wiring constituting the wiring pattern, and a base body on which the connection terminal is fixed, and a casing. The main body is attached to the casing to be movable, the flexible printed circuit board has an extension part protruding from the main body and extending along with a ground included in the wiring pattern, the extension part bends in the middle of extending to be capable of expansion and contraction, and has a mounting part fixed to the casing on the tip side thereof, the mounting part is provided with a ground terminal connected to the ground extended, and the ground terminal is electrically connected to the casing in the state that the mounting part is fixed to the casing.

A data rack system includes a data center rack frame, a shelf positioned within the data center rack frame; and a modular battery unit disposed on the shelf. The modular battery unit further includes a housing having an outer surface, a plurality of strips of phase change material (“PCM”) attached to the outer surface and spaced apart from one another; and air flow channels. The air flow channels are formed in spaces between two adjacent strips of the plurality of strips and defined by a shape and size of the spaces between the two adjacent strips.